Cyclin D1 Expression Mediated by Phosphatidylinositol 3-Kinase through mTOR-p70S6K-Independent Signaling in Growth Factor-Stimulated NIH 3T3 Fibroblasts

Phosphatidylinositol (PI) 3-kinase is required for G₁ to S phase cell cycle progression stimulated by a variety of growth factors and is implicated in the activation of several downstream effectors, including p70^S6K. However, the molecular mechanisms by which PI 3-kinase is engaged in activation of the cell cycle machinery are not well understood. Here we report that the expression of a dominant negative (DN) form of either the p110α catalytic or the p85 regulatory subunit of heterodimeric PI 3-kinase strongly inhibited epidermal growth factor (EGF)-induced upregulation of cyclin D1 protein in NIH 3T3(M17) fibroblasts. The PI 3-kinase inhibitors LY294002 and wortmannin completely abrogated increases in both mRNA and protein levels of cyclin D1 and phosphorylation of pRb, inducing G₁ arrest in EGF-stimulated cells. By contrast, rapamycin, which potently suppressed p70^S6K activity throughout the G₁ phase, had little inhibitory effect, if any, on either of these events. PI 3-kinase, but not rapamycin-sensitive pathways, was also indispensable for upregulation of cyclin D1 mRNA and protein by other mitogens in NIH 3T3 (M17) cells and in wild-type NIH 3T3 cells as well. We also found that an enforced expression of wild-type p110 was sufficient to induce cyclin D1 protein expression in growth factor-deprived NIH 3T3(M17) cells. The p110 induction of cyclin D1 in quiescent cells was strongly inhibited by coexpression of either of the PI 3-kinase DN forms, and by LY294002, but was independent of the Ras-MEK-ERK pathway. Unlike mitogen stimulation, the p110 induction of cyclin D1 was sensitive to rapamycin. These results indicate that the catalytic activity of PI 3-kinase is necessary, and could also be sufficient, for upregulation of cyclin D1, with mTOR signaling being differentially required depending upon cellular conditions.     

Existence of a commitment program for mitosis in early G1 in tumour cells

The proliferation of normal non-tumourigenic mouse fibroblasts is stringently controlled by regulatory mechanisms located in the postmitotic stage of G₁ (which we have designated G₁ pm). Upon exposure to growth factor depletion or a lowered de novo protein synthesis, the normal cells leave the cell cycle from G₁ pm and enter G₀. The G₁ pm phase is characterized by a remarkably constant length (the duration of which is 3 h in Swiss 3T3 cells), whereas the intercellular variability of intermitotic time is mainly ascribable to late G₁ or pre S phase (G₁ ps) (Zetterberg & Larsson (1985) Proc. Natl. Acad. Sci. USA 82 , 5365). As shown in the present study two tumour-transformed derivatives of mouse fibroblasts, i.e. BPA31 and SVA31, did not respond at all, or only responded partially, respectively, to serum depletion and inhibition of protein synthesis. If the tumour cells instead were subjected to 25-hydroxycholesterol (an inhibitor of 3-hydroxy-3 methyglutaryl coenzyme A reductase activity), their growth was blocked as measured by growth curves and [³H]-thymidine uptake. Time-lapse analysis revealed that the cells were blocked specifically in early G₁ (3-4h after mitosis), and DNA cytometry confirmed that the arrested cells contained a G₁ amount of DNA. Closer kinetic analysis revealed that the duration of the postmitotic phase containing cells responsive to 25-hydroxycholesterol was constant. These data suggest that transformed 3T3 cells also contain a ‘G₁ pm program’, which has to be completed before commitment to mitosis. By repeating the experiments on a large number of tumour-transformed cells, including human carcinoma cells and glioma cells, it was demonstrated that all of them possessed a G₁ pm-like stage. Our conclusion is that G₁ pm is a general phenomenon in mammalian cells, independent of whether the cells are normal or neoplastic.     

Cell Cycle Dynamics of Cultured Coral Endosymbiotic Microalgae (Symbiodinium) Across Different Types (Species) Under Alternate Light and Temperature Conditions

Dinoflagellates of the genus Symbiodinium live in symbiosis with many invertebrates, including reef‐building corals. Hosts maintain this symbiosis through continuous regulation of Symbiodinium cell density via expulsion and degradation (postmitotic) and/or constraining cell growth and division through manipulation of the symbiont cell cycle (premitotic). Importance of premitotic regulation is unknown since little data exists on cell cycles for the immense genetic diversity of Symbiodinium. We therefore examined cell cycle progression for several distinct SymbiodiniumITS2‐types (B1, C1, D1a). All types exhibited typical microalgal cell cycle progression, G₁ phase through to S phase during the light period, and S phase to G₂/M phase during the dark period. However, the proportion of cells in these phases differed between strains and reflected differences in growth rates. Undivided larger cells with 3n DNA content were observed especially in type D1a, which exhibited a distinct cell cycle pattern. We further compared cell cycle patterns under different growth light intensities and thermal regimes. Whilst light intensity did not affect cell cycle patterns, heat stress inhibited cell cycle progression and arrested all strains in G₁ phase. We discuss the importance of understanding Symbiodinium functional diversity and how our findings apply to clarify stability of host‐Symbiodinium symbioses.     

Cell density related gene expression: SV40 large T antigen levels in immortalized astrocyte lines

Background

Gene expression is affected by population density. Cell density is a potent negative regulator of cell cycle time during exponential growth. Here, we asked whether SV40 large T antigen (Tag) levels, driven by two different promoters, changed in a predictable and regular manner during exponential growth in clonal astrocyte cell lines, immortalized and dependent on Tag.

Results

Expression and cell cycle phase fractions were measured and correlated using flow cytometry. T antigen levels did not change or increased during exponential growth as a function of the G₁ fraction and increasing cell density when Tag was transcribed from the Moloney Murine Leukemia virus (MoMuLV) long terminal repeat (LTR). When an Rb-binding mutant T antigen transcribed from the LTR was tested, levels decreased. When transcribed from the herpes thymidine kinase promoter, Tag levels decreased. The directions of change and the rates of change in Tag expression were unrelated to the average T antigen levels (i.e., the expression potential).

Conclusions

These data show that Tag expression potential in these lines varies depending on the vector and clonal variation, but that the observed level depends on cell density and cell cycle transit time. The hypothetical terms, expression at zero cell density and expression at minimum G₁ phase fraction, were introduced to simplify measures of expression potential.

     

Threshold expression of cyclin E but not D type cyclins characterizes normal and tumour cells entering S phase

Complexes of cyclin-dependent kinases (cdk) and their partner cyclins drive the cell through the cell cycle, each such complex phosphorylating a distinct set of proteins at a particular check-point or phase of the cycle. Immunocytochemical detection of cyclins combined with measurement of cellular DNA content by flow cytometry makes it possible to relate expression of each of these proteins with the actual cell cycle position, without the necessity of cell synchronization. In the present study, we have investigated expression of E and D type cyclins in G₁ cells and in cells entering S phase, in eight different human hematopoietic and solid tumour cell lines (two leukaemias, a lymphoma, three breast carcinomas, a colon carcinoma and a bladder transitional cell carcinoma) during their exponential phase of growth, as well as in normal mitogen stimulated lymphocytes. In all the cell types studied, the average level of D type cyclin expression was invariable throughout the cell cycle. A great intercellular variability, in particular of the G₁ cell subpopulations, and the presence of a large fraction of G₁, S and G₂+ M cells that were cyclin D negative (20–40% in tumour cell lines and about 80% among lymphocytes), were other characteristic features of D type cyclin expression. In contrast to D type cyclins, the expression of cyclin E was discontinuous during the cycle, peaking at the time of cell entrance to S. Also, a well defined threshold in expression of cyclin E characterized cells that were entering S phase, and virtually no cyclin E negative cells were seen during the early portion of S phase. The data indicate that while cell entrance to S phase is unrelated to expression of D type cyclins (at the time of entrance), accumulation of cyclin E up to critical level is a prerequisite for initiation of DNA replication. The great intercellular variability in expression of D type cyclins and their invariant average level across the cell cycle suggest that these cyclins, in addition to their acknowledged function in promoting cell progression through mid- to late-G₁ may have other role(s), related or unrelated to the cell cycle progression. The presence of a large number of D type cyclin negative cells in all phases of the cycle suggests that during exponential growth the cells may not express this protein and yet may traverse the cycle, including G₁ phase.     

Characterization of AT2 Receptor Expression in NIH 3T3 Fibroblasts

1. A high expression of angiotensin II receptors and of angiotensin-converting enzyme (ACE) activity was detected in confluent NIH 3T3 fibroblasts.2. Characterization with selective ligands, dithiothreitol, and GTPS, indicated that only the AT₂ subtype was expressed.3. AT₂ receptors and ACE expression were strictly dependent on the cell density and growth phase of the cells, with AT₂ receptors being expressed earlier than ACE. In contrast, high expression of AT₂ receptors irrespective of their growth state was observed in NIH 3T3 cells lacking contact inhibition upon neoplastic transformation with ras.4. Our results imply a possible relation of AT₂ receptors to cell growth and cell–cell contact.     

Silence of ClC-3 chloride channel inhibits cell proliferation and the cell cycle via G/S phase arrest in rat basilar arterial smooth muscle cells

Abstract. Objectives: Previously, we have found that the ClC‐3 chloride channel is involved in endothelin‐1 (ET‐1)‐induced rat aortic smooth muscle cell proliferation. The present study was to investigate the role of ClC‐3 in cell cycle progression/distribution and the underlying mechanisms of proliferation. Materials and methods: Small interference RNA (siRNA) is used to silence ClC‐3 expression. Cell proliferation, cell cycle distribution and protein expression were measured or detected with cell counting, bromodeoxyuridine (BrdU) incorporation, Western blot and flow cytometric assays respectively. Results: ET‐1‐induced rat basilar vascular smooth muscle cell (BASMC) proliferation was parallel to a significant increase in endogenous expression of ClC‐3 protein. Silence of ClC‐3 by siRNA inhibited expression of ClC‐3 protein, prevented an increase in BrdU incorporation and cell number induced by ET‐1. Silence of ClC‐3 also caused cell cycle arrest in G₀/G₁ phase and prevented the cells’ progression from G₁ to S phase. Knockdown of ClC‐3 potently inhibited cyclin D1 and cyclin E expression and increased cyclin‐dependent kinase inhibitors (CDKIs) p27^KIP and p21^CIP expression. Furthermore, ClC‐3 knockdown significantly attenuated phosphorylation of Akt and glycogen synthase kinase‐3β (GSK‐3β) induced by ET‐1. Conclusion: Silence of ClC‐3 protein effectively suppressed phosphorylation of the Akt/GSK‐3β signal pathway, resulting in down‐regulation of cyclin D1 and cyclin E, and up‐regulation of p27^KIP and p21^CIP. In these BASMCs, integrated effects lead to cell cycle G₁/S arrest and inhibition of cell proliferation.     

STATIONARY PHASE OF CULTURED MAMMALIAN CELLS (L5178Y)

The stationary phase of the mammalian cells L5178Y in culture can be divided into two stages: (a) an early phase characterized by the decline of mitotic index, followed by a stabilization of the cell number, and (b) a late stage, occurring several hours after the flattening of the growth curve, during which dead or dying cells appear in the cultures. The estimates of rates of cell progress showed that the rates from G₁ to S and from G₂ to M were affected in the early stationary phase. The main cause of cessation of increase in cell number in the early stationary phase is resulted from the decline in mitotic index, which is caused by prolongation of the G₂ period. The importance of the G₂ stage in regulating the cell growth is discussed in relation to other known situations in the literature.     

TGF-β1 perturbation of the fibroblast cell cycle during exponential growth: switching between negative and positive regulation*

Abstract. We have demonstrated previously that SV40 T antigen and serum regulate the length of G₁ in exponentially growing NIH-3T3 cells in part by inhibiting density dependent negative cell cycle regulation. In these studies it was suggested that T antigen positively regulated G₁ in a density independent manner as well. In this report we show that, 24 h after treatment, TGF-β1 perturbs the cell cycle of exponentially growing fibroblasts in a manner similar to T antigen. However, prior to 24 h, TGF-β1 produced a negative response, elongating the Gi phase of the cell cycle that was followed by a positive response, both of which were density independent. This biphasic response was measured between 0 and 12 h post-treatment and was relative to responses from serum. This switch from an early inhibitory effect to a late stimulatory effect was associated with changes in Rb phosphorylation, the timing and magnitude of which indicated that Rb may be directly regulating T_G1 rather than reporting changes in the population. This is further substantiated by abrogation of the inhibitory effect by expression of wild-type SV40 T antigen and retention of the effect in cells that express an Rb-binding mutant of T antigen (K1). The biphasic regulatory effects of TGF-β1 were also displayed in WI-38 and IMR-90 human fibroblasts. This suggests that this biphasic effect is a property of fibroblasts.     

Cadmium cytotoxicity and variation in nuclear content of DNA in Euglena gracilis

Cultures of Euglena gracilis (strain Z from French CNRS collection) can be made cadmium resistant if grown in a medium with 5x10^-4M cadmium chloride. This resistance is reflected by the appearance of a second exponential growth phase. The development of this resistance was studied at the cellular level by determining the relative content of DNA at different stages of the cell cycle in an asynchronously grown culture. The culture was followed until the second, cadmium resistant, growth phase had reached its stationary state. During the first exponential growth phase, cells were mostly in the late period of DNA synthesis (stage S of the cell cycle), or in the gap preceding mitosis (stage G₂ of the cell cycle). In addition, some cells contained high multiples of the normal amount of DNA. In the beginning of the second exponential growth phase, a few cells were again in G₁ (the post mitotic stage of the cell cycle preceding DNA synthesis). These G₁ cells were predominant at the end of the second growth period. During the second stationary phase the DNA content of the cadmium treated cells was similar to the stationary phase of the control culture. Cells had stopped growing in G₁ with an unreplicated genome. The implications of these data are discussed.     

Effects of temperature on growth rate of cultured mammalian cells (L5178Y)

L5178Y cells were cultured in vitro at various temperatures. When the cells were in the exponential growth phase, the cells were in the "steady state of growth," i.e., the fraction of cells in the G₁, S, G₂, and M stages and the durations of each stage were constant. The life cycle analysis of the cells in the steady state of growth demonstrated that the G₁ stage and the S stage were affected the most by variation of temperature, and suggested that these two stages have considerable influence on the growth rate of the L5178Y cells. The calculated activation energies were positive in each stage of the life cycle, whereas the entropies of activation were negative throughout. The possible significance of these findings in our search for the regulatory mechanisms of cell growth is discussed.     

Cultured Human Tumour Cells May Be Arrested In All Stages of the Cycle During Stationary Phase: Demonstration of Quiescent Cells In G1, S and G2 Phase

Six human colon carcinoma cell lines were induced to enter stationary phase of growth by nutrient deprivation and cell crowding. Growth kinetics parameters (cell number, flow cytometric analysis of DNA distribution, and labelling and mitotic indices) were measured sequentially for all lines during the various stages of in vitro growth. Our results demonstrated that a substantial fraction of cells (9–18%) were located in G₂, phase when they changed from an exponential to a stationary mode of growth. Moreover, a large number of cells in stationary phase of growth had an S-phase DNA content, as determined by flow cytometry, but failed to incorporate radioactive DNA precursors (up to 15-fold difference). to substantiate these findings. cells in stationary phase of growth were induced to enter exponential growth by re-seeding in fresh medium at a lower density. Subsequently observed changes in DNA-compartment distribution, and in labelling and mitotic indices were those expected from cells that had been arrested at different stages of the cycle during their previous stationary phase. Thus, the non-proliferating quiescent state (Q), traditionally located ‘somewhere’ in G₁, phase, appears to be composed also of cells that can be arrested at other stages of the cycle (Q_s, and Q_G). Although the proportion of such cells is rather small, their contribution to the growth kinetics behaviour of human in vivo tumours will become apparent following ‘recruiting’ or ‘synchronizing’ clinical manoeuvres and will prevent the formation of a clear-cut wave of synchronized cells.     

Potassium transport and content during G1 and S phase following serum stimulation of 3T3 cells.

The effect of serum stimulation on unidirectional and net K flux and their relationship to the initiation of DNA synthesis has been investigated in mouse 3T3 fibroblasts. Stimulation of quiescent 3T3 cells with 20% serum results in the initiation of S phase approximately ten hours after serum addition. During transition from G₁ to S phase distinct changes in K transport and cellular K content occur. Total unidirectional K influx undergoes an immediate 2-fold increase upon serum addition, an observation in qualitative agreement with previous results (Rozengurt and Heppel, 1975). This total increase in unidirectional K influx represents a proportional increase in the active, ouabain sensitive component and the K-K exchange component. The initial increase in total flux is followed by a gradual decline over a 16-hour period to levels approaching those of quiescent cells. Following the initial increase in unidirectional K influx is an approximately 75% increase in cell K on a per milligram protein basis or a 40% increase on a per volume basis. This increase peaks at four to five hours and then declines to initial levels at 10 to 14 hours. Populations of quiescent cells given 20% serum plus 0.5 mM ouabain simultaneously are totally blocked from entering S phase, as determined by the appearance of ³H-thymidine labeled nuclei. However, if the ouabain is removed after six hours these cells then undergo the same changes in unidirectional K influx and content as serum stimulated cells with entrance into S phase retarded by five to six hours. If ouabain is added to serum stimulated cells at six hours, after the increase in K transport and K content have occurred, entrance into S phase is not entirely blocked. In cells stimulated with serum and 0.5 mM dBcAMP plus 1 mM theophylline simultaneously, entrance into S phase is greatly reduced as compared to serum stimulation only. However, the early and late changes in K flux and K content are not substantially altered. This indicates that the K transport events associated with G₁ and early S phase are not directly regulated by changes in cAMP levels which follow serum stimulation.     

Defective autophagy in multidrug resistant cells may lead to growth inhibition by BH3‐mimetic gossypol

The clinical efficacy of many chemotherapeutic agents has been reduced due to the development of drug resistance. In this article, we aimed to validate gossypol, a natural BH3 mimetic found in cottonseeds, as a potential therapeutic to overcome multidrug resistance (MDR). Gossypol was found to retain its efficacy in v‐Ha‐ras‐transformed NIH 3T3 cells that overexpressed P‐glycoprotein (Ras‐NIH 3T3/Mdr), which was similar to the efficacy observed in their parental counterparts (Ras‐NIH 3T3). A rhodamine assay revealed that the alteration of MDR activity did not contribute to the cytotoxic effect of gossypol. Gossypol caused a G₂/M arrest by the induction of p21^Cip1 and the down‐regulation of p27^Kip1 expression in Ras‐NIH 3T3 cells, whereas no significant G₂/M arrest was exhibited in Ras‐NIH 3T3/Mdr cells. Surprisingly, a 48‐h treatment with gossypol induced apoptotic cell death in Ras‐NIH 3T3 cells; however, gossypol induced both apoptosis and necrosis in Ras‐NIH 3T3/Mdr cells, as determined with flow cytometry analysis. More notably, gossypol preferentially induced autophagy in Ras‐NIH 3T3 cells but not in Ras‐NIH 3T3/Mdr cells. Coimmunoprecipitation and flow cytometric analysis revealed that gossypol‐induced autophagy is independent of the dissociation of Beclin 1 from Bcl‐2 in Ras‐NIH 3T3 cells. Taken together, these results suggest that the antiproliferative activity of gossypol appears to be due to cell‐cycle arrest at the G₂/M phase, with the induction of apoptosis in Ras‐NIH 3T3 cells. In addition, defective autophagy might contribute to apoptotic and necrotic cell death in response to gossypol in Ras‐NIH 3T3/Mdr cells. J. Cell. Physiol. 228: 1496–1505, 2013. © 2012 Wiley Periodicals, Inc.     

Effects of inhibition of RNA or protein synthesis on CHO cell cycle progression

Chinese hamster ovary (CHO) cells, synchronized by selective detachment at mitosis, were treated with various concentrations of actinomycin D (AMD) or cycloheximide (CHX) either immediately, or 1, 2, or 3 hr after mitosis. Since the minimum duration of G₁ phase in these cultures was 3.4 hr, the addition of RNA or protein synthesis inhibitors took place at the beginning, first third, second third, or end (G₁–S boundary) of G₁ phase. The kinetics of exit from G₁ phase, the rate and extent of traverse of S phase, and the reaccumulation of RNA were estimated under each set of growth conditions by flow cytometry of acridine orange-stained cells. A mathematical model was constructed to describe the trajectories of the cell populations with respect to their increase in RNA and DNA content in the absence or presence of the inhibitor. The chronologic synchrony imposed on the CHO cell population began to decay within 3 hr, resulting in stochastic entrance of cells into S phase in the absence of inhibitor. Addition of AMD or CHX at 0, 1, 2, or 3 hr after mitosis, regardless of the inhibitor concentration, did not provide evidence of a critical restriction point in G₁ beyond which cells were committed to enter S phase and were no longer sensitive to moderate suppression of RNA or protein synthesis. The observed kinetics of cell entrance into and traverse of S phase were consistent with an inherently heterogenous response to serum stimulation occurring at or just after cell division.     

Variation In G1 Transit Time Relative to the Cycloheximide and Actinomycin D Drug Restriction Points

The transit time distribution at various points in the cell cycle of synchronized Chinese hamster ovary cells was determined from the mitotic index, [³H]thymidine labeling index and increase in cell number monitored at regular intervals after mitotic selection. Variation in G₁ transit time compared with that for the total cell cycle indicates that variation in cell cycle transit time occurs mainly during G₁ phase. the cycloheximide (5.0 μg/ml) and actinomycin D (3.0 μg/ml) restriction points occur 0.2 and 1.7 hr prior to entry into S phase, respectively. the transit time distributions are further characterized by the moments of the distributions. the variance (2nd moment about the mean) of the transit time distribution at the actinomycin D restriction point is similar to the variance of the transit time distribution at the G₁/S border, thus variation in cell cycle transit time originates earlier than 1.7 hr prior to entry into S phase (i.e., the first 3/4 of G₁). If G₁ transit time variability and cell cycle control are related, then the results presented here indicate that the major regulatory events do not occur during late G₁ phase.