Formation of proliferative tetraploid cells after treatment of diploid cells with sodium butyrate in rat 3Y1 fibroblasts

When randomly proliferating rat 3Y1 fibroblasts were treated with sodium butyrate, more than 90% of their cells were arrested reversibly with a 2C DNA content at least 12 h before the G1/S boundary. When cells synchronized in the early S phase were treated with butyrate, approximately 70% of all cells were arrested with a 4C DNA content. The arrests in both G1 and G2 phases by the single inhibitor suggest that the two phases share a common mechanism. The ability of cells to undergo mitosis on time was quickly lost with time of arrest in the G2 phase. Upon removal of the inhibitor, the cells arrested with a 4C DNA content entered a new S phase without intervening mitosis. The tetraploid cells thus produced kept proliferating as fast as diploid cells. These results suggest that the inhibition of the normal G2 traverse is somehow responsible for the formation of the proliferative polyploid cells.     

Cell cycle analysis of sodium butyrate and hydroxyurea, inducers of ectopic hormone production in HeLa cells

Sodium butyrate and hydroxyurea, effective inhibitors of DNA synthesis in HeLa cells, cause these cells to produce increased levels of the ectopic glycopeptide hormones human chorionic gonadotropin (hCG), follicle stimulating hormone (FSH), and free alpha chains for these hormones. The objective of this study was an assessment of the role of modulation of cell cycle events in the action of these two chemical agents. A variety of experimental approaches was employed to obtain a clear view of the drugs' effects on cells located initially in all phases of the cell cycle. Cells in early G1, G2, or M phase at time of addition of either inhibitor were not arrested at early time points, but by 48 hours became collected at a location characteristic for each drug, near the G1-S phase boundary. Flow microfluorometry (FMF) and thymidine labeling index revealed that butyrate-treated cells arrested late in G1 phase very close to S phase, while hydroxyurea-blocked cells continued to early S phase. Both inhibitors prevented cells originally in S phase from reaching mitosis. S cells exposed to hydroxyurea were killed by 48 hours, but those growing in 5 mM butyrate progressed to the end of S or G2 phase where they became irreversibly arrested although not removed from the monolayer. Analysis of the cell cycle location and viability of each subpopulation resulting from 48 hour exposure to butyrate or hydroxyurea is important for the study of the function of each cellular subset. Treatment of HeLa cells with lower concentrations of butyrate (1 mM) resulted in slowed yet exponential growth. Fraction labeled mitosis (FLM) analysis shows that this is a result of prolongation of the G1 phase.     

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.     

Assessment of cell viability by flow cytometric analysis using DNase exclusion

A new method was developed for selective measurement of DNA distributions in viable cell populations. The method is based on the fact that non-viable cells lose membrane integrity and treatment of such cells with DNase should remove their DNA. The DNase-treated cells were stained with DNA fluorochrome 4′-6-diamidino-2-phenylindole (DAPI) in the presence of Triton X-100. DNA distribution was measured by flow cytometry prior to and after treatment with DNase. Percentage of cells stained after DNase treatment was considered as an index of cell viability. Optimal conditions for DNase treatment and application of DNase exclusion test for the analysis of spontaneous cell death, selective death of cells arrested in S/G2 phases, instant cell disintegration induced by cytotoxic compounds and cell death induced by hyperthermia are described.     

Cell cycle dependent distribution of the proliferation-associated Ki-67 antigen in human embryonic lung cells

The cell cycle-dependent distribution of the proliferation-associated Ki-67 antigen has been evaluated immunocytochemically in L-132 human fetal lung cells. The cells were synchronized and cell cycle phases were determined: G1 = 6.7 h, S = 5.4 h, G2 = 8.5 h and mitosis = 1.3 h. The Ki-67 patterns were strictly correlated with the cell cycle phases. In late G1-phase, Ki-67 antigen was present only in the perinucleolar region. In the S-phase, Ki-67 staining was found homogeneously in the karyoplasm and in the perinucleolar region. G2-phase cells contained a finely granular Ki-67 staining in the karyoplasm with Ki-67-positive specks and perinucleolar staining. In early mitotic cells (pro- and metaphase) an intense perichromosomal Ki-67 staining was observed in addition to a homogeneously stained karyoplasm in prophase, and cytoplasm in metaphase. During ana- and telophase the Ki-67 antigen disappeared rapidly. In resting cells there was no Ki-67 staining.     

A model of cell cycle control: effects of thymidine on synchronous cell cultures.

Further evidence is presented in support of a model for growth control in which commitment for cell division is determined by an event in the preceding cell cycle. A study was made of conditions affecting synchronous growth following treatment of murine mastocytoma cells with excess thymidine at different phases of the cell cycle. Cells were synchronized by a physical procedure involving velocity sedimentation in a zonal rotor. Pulse treatment of such cultures with thymidine at times corresponding to the S, G2, and M periods had no effect on further growth. However, addition at G1, although having no immediate effect, arrested cell growth in the next cell cycle. This temporal effect may account for the decay of synchrony observed during double thymidine blockade or thymidine-FUdR blockade. When the time interval between two such blocks was 7 hr or less, P815Y cells were arrested after one synchronous division. At this critical time a majority of cells were at, or near, G1. It is suggested that thymidine exerts a hitherto unrecognized effect at the G1 interval.     

Cell cycle phase expansion in nitrogen-limited cultures of Saccharomyces cerevisiae

The time and coordination of cell cycle events were examined in the budding yeast Saccharomyces cerevisiae. Whole-cell autoradiographic techniques and time-lapse photography were used to measure the duration of the S, G1, and G2 phases, and the cell cycle positions of "start" and bud emergence, in cells whose growth rates were determined by the source of nitrogen. It was observed that the G1, S, and G2 phases underwent a proportional expansion with increasing cell cycle length, with the S phase occupying the middle half of the cell cycle. In each growth condition, start appeared to correspond to the G1 phase/S phase boundary. Bud emergence did not occur until mid S phase. These results show that the rate of transit through all phases of the cell cycle can vary considerably when cell cycle length changes. When cells growing at different rates were arrested in G1, the following synchronous S phase were of the duration expected from the length of S in each asynchronous population. Cells transferred from a poor nitrogen source to a good one after arrest in G1 went through the subsequent S phase at a rate characteristic of the better medium, indicating that cells are not committed in G1 to an S phase of a particular duration.     

Sodium butyrate induces G2 arrest in the human breast cancer cells MDA-MB-231 and renders them competent for DNA rereplication

When exposed to sodium butyrate (NaBut), exponentially growing cells accumulate in G1 and G2 phases of the cell cycle. In the human breast cancer cell line MDA-MB-231, an arrest in G2 phase was observed when the cells were released from hydroxyurea block (G1/S interface) in the presence of NaBut. The inhibition of G2 progression was correlated with increased contents both of total p21(Waf1) and of p21(Waf1) associated with cyclin A and with an inhibition of cyclin A- and B1-associated histone H1 kinase activities measured in cell lysates, as well as with dephosphorylation of the RB protein. A decrease in the cell contents of cyclins A and B1 was also observed but this decrease was preceded by p21(Waf1) accumulation. When NaBut was removed from the culture medium of cells blocked in G2 phase, p21(Waf1) level decreased and, instead of proceeding to mitosis, these cells resumed a progression toward DNA rereplication. These results suggest that the induction of p21(Waf1) by NaBut leads to the inhibition of the sequential activation of cyclin A- and B1-dependent kinases in this cell line, resulting in the inhibition of G2 progression and rendering the cells competent for a new cell division cycle.     

Gene-specific characterization of human histone H2B by electron capture dissociation

The basis set of protein forms expressed by human cells from the H2B gene family was determined by Top Down Mass Spectrometry. Using Electron Capture Dissociation for MS/MS of H2B isoforms, direct evidence for the expression of unmodified H2B.Q, H2B.A, H2B.K/T, H2B.J, H2B.E, H2B.B, H2B.F, and monoacetylated H2B.A was obtained from asynchronous HeLa cells. H2B.A was the most abundant form, with the overall expression profile not changing significantly in cells arrested in mitosis by colchicine or during mid-S, mid-G2, G2/M, and mid-G1 phases of the cell cycle. Modest hyperacetylation of H2B family members was observed after sodium butyrate treatment.     

Induction of endoreduplication in temperature-sensitive mutants of rat 3Y1 fibroblasts

Four temperature-sensitive mutants of rat 3Y1 fibroblasts belonging to separate complementation groups (3Y1tsD123, 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203) are arrested mainly with a 2C DNA content, when cells proliferating at 33.8 degrees C are shifted up to 39.8 degrees C (Ohno et al., 1984). Zaitsu and Kimura (submitted for publication) showed that 3Y1tsF121 cells synchronized in the early S phase were arrested with a 4C DNA content at 39.8 degrees C. We studied the traverse through the S and G2 phases at 39.8 degrees C in the four ts mutants synchronized at the early S phase and found that 3Y1tsG125 and 3Y1tsH203 cells were arrested with a 4C DNA content as 3Y1tsF121, while 3Y1tsD123 cells went through S and G2 phases and underwent mitosis. When 3Y1tsF121 and 3Y1tsG125 mutants arrested at 39.8 degrees C were shifted down to 33.8 degrees C, a substantial fraction of the cells with a 4C DNA content started, with a certain lag period, DNA synthesis without intervening mitosis and underwent the first mitosis with a lag period similar to that in the cells arrested with a 2C DNA content. The tetraploid cells thus generated had a proliferating ability lower than that of diploid cells.     

C-banding of Peromyscus constitutive heterochromatin persists following histone hyperacetylation

Approx. 35% of the DNA of cultured cells from the cactus mouse, Peromuscus eremicus, is contained in highly condensed constitutive heterochromatin which can be visualized in metaphase chromosomes stained by the C-band technique. Previous studies have shown this constitutive heterochromatin to contain a large proportion of underacetylated, arginine-rich histones, the majority of which can be hyperacetylated when cells are treated with butyrate. In order to determine whether this simulation of the acetylated state of euchromatin alters the cytological properties of constitutive heterochromatin as well, chromosomes from butyrate-treated cells have been examined. Because of the paucity of cells in butyrate-treated cultures, prematurely condensed chromosomes (PCCs) were produced from butyrate-treated cells by fusion with mitotic cells. In these PCCs, both the highly condensed nature and the ability to C-band were preserved in the hyperacetylated constitutive heterochromatin, suggesting that the subset of arginine-rich histones which is refractory to acetylation in the presence of butyrate may be responsible for the maintenance of the heterochromatic state. In addition, PCC analyses indicated that butyrate arrests Peromyscus cells in both the G1 and G2 phases of the cell cycle and confirmed the late-replicating pattern of constitutive heterochromatin.     

Point mutations in a hinge linking the small and large domains of beta-actin result in trapped folding intermediates bound to cytosolic chaperonin CCT

The 30-A cryo-EM-derived structure of apo-CCT-alpha-actin shows actin opened up across its nucleotide-binding cleft and binding to either of two CCT subunit pairs, CCTbeta-CCTdelta or CCTepsilon-CCTdelta, in a similar 1:4 arrangement. The two main duplicated domains of native actin are linked twice, topologically, by the connecting residues, Q137-S145 and P333-S338, and are tightly held together by hydrogen bonding with bound adenine nucleotide. We carried out a mutational screen to find residues in actin that might be involved in the huge rotations observed in the CCT-bound folding intermediate. When two evolutionarily highly conserved glycine residues of beta-actin, G146 and G150, were changed to proline, both mutant actin proteins were poorly processed by CCT in in vitro translation assays; they become arrested on CCT. A three-dimensional reconstruction of the substrate-bound ring of the apo-CCT-beta-actin complex shows that beta-actin G150P is not able to bind across the chaperonin cavity to interact with the CCTdelta subunit. beta-actin G150P seems tightly packed and apparently bound only to the CCTbeta and CCTepsilon subunits, which further indicates that these CCT subunits drive the interaction between CCT and actin. Hinge opening seems to be critical for actin folding, and we suggest that residues G146 and G150 are important components of the hinge around which the rigid subdomains, presumably already present in early actin folding intermediates, rotate during CCT-assisted folding.     

Prothymosin alpha expression is associated to cell division in rat testis

Using immunohistochemical methods, we have investigated the cellular distribution of prothymosin alpha (ProT) in adult rat testis. A policlonal antibody raised against thymosin alpha 1 conjugated to keyhole limpet hemocyanin was used. ProT immunoreactivity was observed in the cytoplasm and nucleus of spermatogonia and primary spermatocytes in initial phases of the first meiotic division, preleptotene, leptotene and zygotene. However, in pachytene phase they already showed a weak or negative staining. On the other hand, secondary spermatocytes, spermatids, spermatozoa and Sertoli cells were not stained. Based on this fact we suggest that ProT is present in the proliferative cycle in the final steps of G1 phase, throughout the S and G2 phases and in initial steps of the prophase.     

Primary and compensatory roles for RB family members at cell cycle gene promoters that are deacetylated and downregulated in doxorubicin-induced senescence of breast cancer cells

When treated with DNA-damaging chemotherapy agents, many cancer cells, in vivo and in vitro, undergo a terminal growth arrest and acquire a senescence-like phenotype. We investigated the molecular basis for this in breast cancer cells following a 2-hour treatment with 1 muM doxorubicin. Treated cells arrested in G1 and G2 phases of the cell cycle, with concomitant reductions in S-phase and G2-M regulatory genes. p53 and p21 protein levels increased within hours after treatment and were maintained for 5 to 6 days but were reduced 8 days posttreatment, though the cells remained growth arrested. Levels of p130 rose after drug treatment, and it was the primary RB family member recruited to the S-phase promoters cyclin A and PCNA and G2-M promoters cyclin B and cdc2, remaining present for the entire 8-day time period. In contrast, p107 protein and promoter occupancy levels declined sharply after drug treatment. RB was recruited to only the PCNA promoter. In MCF-7 cells with p130 knockdown, p107 compensated for p130 loss at all cell cycle gene promoters examined, allowing cells to retain the growth arrest phenotype. Cells with p130 and p107 knockdown similarly arrested, while cells with knockdown of all three family members failed to downregulate cyclin A and cyclin B. These results demonstrate a mechanistic role for p130 and compensatory roles for p107 and RB in the long-term senescence-like growth arrest response of breast cancer cells to DNA damage.     

Relationship between organization of the actin cytoskeleton and the cell cycle in normal and adenovirus-infected rat cells.

Flow cytometry and staining with 7-nitrobenz-2-oxa-1,3-diazole-phallacidin were used to investigate organization of the actin cytoskeleton in rat embryo cells at different stages of normal and adenovirus E1A-induced cell cycles. In uninfected cells in G0-G1 and S phases, actin was predominantly in the form of stress fibers. In G2, this organization changed to peripheral rings of thin filaments, while during mitosis, actin had a diffuse distribution. Infection of quiescent rat cells by adenovirus caused them to enter the cell cycle and replicate DNA and also caused disruption of stress fibers. Rapid disappearance of stress fibers and the appearance of peripheral rings of actin filaments began from 13 h after infection and closely followed synthesis of the E1A proteins. Infected cells began S phase at about 24 h after infection, and cells in G2 and mitosis were seen from 30 to 50 h. Thus, disruption of the actin cytoskeleton is an early effect of E1A and not an indirect consequence of the entry of infected cells into the cell cycle.     

Flow cytometry of the differentiation of Physarum polycephalum myxamoebae to cysts

Myxamoebae of Physarum polycephalum, strain Cld, were grown on agar lawns on live bacteria. Myxamoebae were harvested, fixed and stained with propidium iodide. Flow cytometry showed that, as in the case of Physarum plasmodia, there is no G1 phase during rapid exponential growth. However, an apparent G1 phase was observed at the end of exponential growth when the culture arrested with the G1 DNA content for about a day between growth and differentiation. Most myxamoebae differentiated into cysts, but some formed microplasmodia and others appeared to lose DNA. The cysts possessed the G2 phase DNA content and there was an S phase connecting the G1-arrested state with the encysted state. Encystment was blocked by hydroxyurea (HU) suggesting that DNA synthesis is essential for encystment. The natural temporary synchronization in G1 phase may provide the basis of a method for selecting mutants with a conditional block in G2 or M phases.     

Polyamine starvation prolongs the S and G2 phases of polyamine-dependent (arginase-deficient) CHO cells.

This study analyzes the effects of polyamine starvation on cell cycle traverse of an arginase-deficient CHO cell variant (CHO-A7). These cells grow well in serum-free medium, provided that it contains ornithine or polyamines or both. In the absence of ornithine or polyamines or both, the CHO-A7 cells develop severe polyamine deficiency and, as a consequence, grow more slowly. When grown to a stationary phase in the presence of ornithine or putrescine or both, the CHO-A7 cells became arrested in G0/early G1. However, when starved for ornithine and polyamines, they accumulated in the S and G2 phases. Ornithine and polyamine starvation of CHO-A7 cells causes an increase in ornithine decarboxylase activity. When this increase was prevented by treatment with DL-alpha-difluoromethylornithine, an enzyme-activated irreversible inhibitor of ornithine decarboxylase, growth was further suppressed, and a greater fraction of cells were found in the S and G2 phases of the cell cycle.     

The dynamics of the actin cytoskeleton during sporogenesis in Psilotum nudum L.

The actin cytoskeleton (microfilaments, MFs) accompanies the tubulin cytoskeleton (microtubules) during the meiotic division of the cell, but knowledge about the scope of their physiological competence and cooperation is insufficient. To cast more light on this issue, we analysed the F-actin distribution during the meiotic division of the Psilotum nudum sporocytes. Unfixed sporangia of P. nudum were stained with rhodamine-phalloidin and 4′,6-diamidino-2-phenylindole dihydrochloride, and we monitored the changes in the actin cytoskeleton and nuclear chromatin throughout sporogenesis. We observed that the actin cytoskeleton in meiotically dividing cells is not only part of the kariokinetic spindle and phragmoplast but it also forms a well-developed network in the cytoplasm present in all phases of meiosis. Moreover, in telophase I F-actin filaments formed short-lived phragmoplast, which was adjacent to the plasma membrane, exactly at the site of future cell wall formation. Additionally, the meiocytes were pre-treated with cytochalasin-B at a concentration that causes damage to the MFs. This facilitated observation of the effect of selective MFs damage on the course of meiosis and sporogenesis of P. nudum. Changes were observed that occurred in the cytochalasin-treated cells: the daughter nuclei were located abnormally close to each other, there was no formation of the equatorial plate of organelles and, consequently, meiosis did not occur normally. It seems possible that, if the actin cytoskeleton only is damaged, regular cytokinesis will not occur and, hence, no viable spores will be produced.     

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.