DNA SYNTHESIS AND MITOSIS IN MERISTEMS: REQUIREMENTS FOR RNA AND PROTEIN SYNTHESIS

Following provision of sucrose to starved, stationary phase pea root meristems, G₁ and G₂ cells enter DNA synthesis and mitosis, respectively. Puromycin (450 μg/ml) and cycloheximide (5 μg/ml) completely prevent this initiation of progression through the cell cycle. Actinomycin D (10 μg/ml) has no effect on the initial entry of G₁ and G₂ cells into S and mitosis, although later entry is prevented. The resistance of the cells to actinomycin D is lost slowly with time in medium without sucrose, suggesting that an RNA required for the resumption of proliferative activity is being gradually lost. The effects of the inhibitors on transitional and proliferative phase meristem cells indicate that such dividing cells do indeed have sufficient of the requisite RNA for 8-12 hr progression through the cycle, but that protein synthesis is required continuously. It is suggested that this RNA is the one lost slowly during starvation, allowing starved cells to reinitiate progression through the cycle in the presence of actinomycin D.     

Regulation of mitotic activity and the cell cycle in primary chick muscle cells by neurotransferrin

We previously demonstrated that neurotransferrin (NTF), a transferrin extracted from adult chicken peripheral nerves, promotes growth of primary chick muscle cells in the absence of embryo extract. NTF was shown to stimulate DNA synthesis and cell proliferation. In the present study, we demonstrate that NTF is a mitogen using two independent methods; counts of orcein-stained mitotic figures and analysis of cell cycle kinetics with a fluorescence-activated cell sorter. In low-density cultures mitotic activity increases with increasing doses of NTF followed by a plateau at concentrations greater than 6 μg/ml. Residual, embryonic mitotic activity progressively declines with time after plating muscle cells in the absence of NTF. Absence of NTF for 2 days causes cells to lose irreversibly their myogenic potential. In the presence of NTF, mitotic activity increases for 2 days followed by a decline concurrent with myoblast fusion and formation of myotubes. Cell cycle analysis showed that NTF addition causes cell populations to shift from G_t to S and G₂ + M within 18.5 hr. Muscle cells, plated at high densities in the absence of NTF, show mitotic activities similar to those plated at low densities in the presence of NTF. Addition of NTF to high-density cultures is ineffective in stimulating mitosis. These studies show that at typical cell plating densities, NTF is a required mitogen for primary chick muscle cell cultures.     

Relative resistance to methothexate by proliferating normal rabbit epidermal cells in vitro

Summary Primary cell cultures of normal rabbit epidermal cells (keratinocytes) were established without the use of enzymatic techniques. Six experiments were carried out on cells from six different rabbits. When these cells were exposed to methotrexate (MTX) for 24 h at 1 μg/ml, proliferation, as measured by cells entering mitosis, was significantly inhibited (P<0.05) in only one experiment. When the dose of MTX was elevated to 100 μg/ml, only two experiments showed significant inhibition of mitosis. This minimal inhibition of mitosis by MTX was contrasted by the dramatic inhibitory effect of this antimetabolite on DNA synthesis. At 1 μg/ml MTX for 24 h, DNA synthesis, as measured by [³H]deoxyuridine uptake, was inhibited >95%. We can conclude that under certain conditions, the rabbit keratinocyte may represent a normal cell type that is inherently resistant to the antiproliferative effects of methotrexate. The research was supported by National Cancer Institute Grant CA 11536.     

DNA synthesis and cell proliferation in C6 glioma and primary glial cells exposed to a 836.55 MHz modulated radiofrequency field

We have tested the hypothesis that modulated radiofrequency (RF) fields may act as a tumor-promoting agent by altering DNA synthesis, leading to increased cell proliferation. In vitro tissue cultures of transformed and normal rat glial cells were exposed to an 836.55 MHz, packet-modulated RF field at three power densities: 0.09, 0.9, and 9 mW/cm², resulting in specific absorption rates (SARs) ranging from 0.15 to 59 μW/g. TEM-mode transmission-line cells were powered by a prototype time-domain multiple-access (TDMA) transmitter that conforms to the North American digital cellular telephone standard. One sham and one energized TEM cell were placed in standard incubators maintained at 37 °C and 5% CO₂. DNA synthesis experiments at 0.59–59 μW/g SAR were performed on log-phase and serum-starved semiquiescent cultures after 24 h exposure. Cell growth at 0.15–15 μW/g SAR was determined by cell counts of log-phase cultures on days 0, 1, 5, 7, 9, 12, and 14 of a 2 week protocol. Results from the DNA synthesis assays differed for the two cell types. Sham-exposed and RF-exposed cultures of primary rat glial cells showed no significant differences for either log-phase or serum-starved condition. C₆ glioma cells exposed to RF at 5.9 μW/g SAR (0.9 mW/cm²) exhibited small (20–40%) significant increases in 38% of [³H]thymidine incorporation experiments. Growth curves of sham and RF-exposed cultures showed no differences in either normal or transformed glial cells at any of the power densities tested. Cell doubling times of C₆ glioma cells [sham (21.9 ± 1.4 h) vs. field (22.7 ± 3.2 h)] also demonstrated no significant differences that could be attributed to altered DNA synthesis rates. Under these conditions, this modulated RF field did not increase cell proliferation of normal or transformed cultures of glial origin. Bioelectromagnetics 18:230–236, 1997. © 1997 Wiley-Liss, Inc.     

Stimulation of density-inhibited cell cultures by insulin

Cell proliferation in density-inhibited chick embryo cell cultures was induced by microgram quantities of insulin, neuraminidase, trypsin or papain. Other proteins tested, including albumin, fetuin, ribonuclease and hyaluronidase were inactive except in very high concentrations (> 100 μg/ml). The insulin chick embryo model was selected for detailed analysis of the initiation of proliferation. Insulin insolubilized by conjugation with Sepharose particles was also active, but only in so far as it was released in soluble form from the particles. This was measured by a radioimmunoassay. Under the conditions giving maximal cell proliferation less than 0.002-0.2% of insulin was taken up by the cells. This suggests that an interaction of insulin with the cell surface only is sufficient to stimulate the cells. Insulin released the density-inhibited cells from G₁ phase to produce an almost synchronous wave of proliferation. The following sequence of events was characteristic of the cells after stimulation by insulin: an early increase in sugar uptake and decrease in leucine uptake, increase in cell volume, stimulation of RNA and protein synthesis, increase in thymidine uptake, DNA synthesis, mitosis and cell division.     

Can Nocodazole,an Inhibitor of Microtubule Formation,Be Used to Synchronize Mammalian Cells?

Abstract Nocodazole, a temporary inhibitor of microtubule formation, has been used to partly synchronize Ehrlich ascites tumour cells growing in suspension. the gradual entry of cells into mitosis and into the next cell cycle without division during drug treatment has been studied by flow cytometric determination of mitotic cells, analysing red and green fluorescence after low pH treatment and acridine orange staining. Determination of the mitotic index (MI) by this method has been combined with DNA distribution analysis to measure cell-cycle phase durations in asynchronous populations growing in the presence of the drug. With synchronized cells, it was shown that in the concentration range 0.4–4.0 μg/l, cells could only be arrested in mitosis for about 7 hr and at 0.04 μg/ml, for about 5 hr. After these time intervals, the DNA content in nocodazole-blocked cells was found to be increased, and, in parallel, the ratio of red and green fluorescence was found to have changed, showing entry of cells into a next cell cycle without division (polyploidization). It was therefore only possible to partially synchronize an asynchronous population by nocodazole. However, a presynchronized population, e.g. selected G₁ cells or metabolically blocked G₁/S cells, were readily and without harmful effect resynchronized in M phase by a short treatment (0.4 μg/ml, 3–4 hr) with nocodazole; after removal of the drug, cells divided and progressed in a highly synchronized fashion through the next cell cycle.     

Conditionally lethal mutations in Chinese hamster cells. I. Isolation of a temperature-sensitive line and its investigation by cell cycle studies

The isolation of a temperature sensitive cell line from the Chinese hamster line CCL39 of the American Type Culture Collection is described. At the nonpermissive temperature (39°C) the cells become attached to the surface of tissue culture dishes, but no microscopically observable colonies are formed upon prolonged incubation. Exposure to the high temperature for more than 24 hours leads to an almost complete loss in viability. A karyotypic analysis showed that this new line has lost one of the medium-sized metacentric chromosomes, although no proof is available so far to show that this loss is not simply coincidental. In nonsynchronized cultures transferred to 39°C DNA synthesis stops first, RNA synthesis shortly thereafter, while protein synthesis (turnover) continues for a longer time. After such a shift the cell number increases by less than 15% as measured with the Coulter counter. Studies with synchronized cultures give the following results: (1) one round of DNA synthesis can occur at 39°C when the cells are released from serum starvation or a hydroxyurea block, or when mitotic cells are placed at 39°C; (2) the entry of cells into metaphase of mitosis at 39°C is almost normal when the preceding time interval at 39°C is only eight hours (release of cells from G₁/S boundary), but considerably reduced when the cells spend an additional 12 to 15 hours at 39°C in G₁ (release from serum starvation). Infection by SV40 virus temporarily induces DNA synthesis after it has come to a stop at the nonpermissive temperature, but cells permanently transformed by SV40 still exhibit the temperature-sensitive phenotype.     

DNA synthesis and mitosis in a temperature sensitive Chinese hamster cell line

Viability, DNA synthesis and mitosis have been followed in the temperature sensitive Chinese hamster cell mutant K12 under permissive and non-permissive conditions. On incubation at 40°C cells retained their ability to form colonies at 33°C for 15 to 20 hours, but viability was lost gradually during the following 20 hours. When random cultures of K12 were shifted to 40°C the rate of DNA synthesis was normal for three to four hours but then decreased markedly, reaching 95% inhibition after 24 hours. Under the same conditions mitosis was inhibited after 15 hours. If cultures which had been incubated at 40°C for 16 hours were placed at 33°C the rate of DNA synthesis increased five hours after the shift down and mitosis 18 hours after. These results can be interpreted on the assumption that K12 at 40°C is unable to complete a step in the cell cycle which is essential for DNA synthesis and which occurs three to four hours before the start of S at 33°C.     

Effect of Thymine Limitation on Chromosomal Deoxyribonucleic Acid Synthesis in Proteus mirabilis

The effects of thymine limitation on the rates of growth, deoxyribonucleic acid (DNA) synthesis, and increase in viable cell number for a thymine auxotroph of Proteus mirabilis were investigated. At thymine concentrations of 1.0 mug/ml and below, these rates were markedly decreased. After a reduction in thymine concentration from 10 mug/ml to 0.2 mug/ml, mass synthesis continued at the preshift rate for several hours. In contrast, the rate of DNA synthesis immediately decreased, resulting in a decrease in the DNA to mass ratio to about one-half of its normal level. Viable counts remained constant for several hours after the reduction in thymine concentration, and enlarged cells and multicellular "snakes" were formed. The rate of DNA synthesis was reduced at thymine concentrations below approximately 1.7 mug/ml. The addition of thymine to cultures which had been completely starved for thymine increased the rate of DNA synthesis to at least twice its normal value; this suggests that extra rounds of chromosome replication can be induced in P. mirabilis as previously observed in Escherichia coli.     

In vitro DNA synthesis as indicator of mammary epithelial cell division: [14C]thymidine uptake versus flow cytometry cell cycle analysis

Summary Mammary and adipose explants from eight mid-lactation Holstein cows were co-cultured for 24 h in the presence or absence of liver explants, 1 μg/ml pituitary bovine somatotrophin, or 100 ng/ml insulinlike growth factor-I. Liver explants in the media significantly depressed DNA and protein synthesis by mammary tissue as measured by [¹⁴C]-thymidine and amino acid incorporation. As measured by flow cytometry, the concentration of DNA in the G₀G₁ and G₂M cells and the percentage of cells in the G₀G₁ population of mammary tissue was also significantly depressed by liver tissue. Changes in the percentage of cells in the S and G₂M phases were not significant. Insulinlike growth factor-I in the presence of liver explants depressed protein synthesis, thymidine incorporation, and the concentration of DNA in the G₀G₁ and G₂M cells compared to control but did not affect the percentage of cells in the G₀G₁, S, or G₂M phases. Previously it was assumed that changes in [¹⁴C]thymidine incorporation indicated that changes in cell division were occurring. Flow cytometry revealed that changes in DNA content of mammary cells as a result of liver or hormonal stimulation were not due to changes in cell division. Indications are that differences in cellular DNA content result from changes in the rate of amplification of individual genes responsible for milk protein synthesis.     

Effect of staurosporine on MOLT-4 cell progression through G2 and on cytokinesis

Staurosporine (SSP) is an inhibitor of a variety of protein kinases with an especially high affinity towards protein kinase C. Whereas SSP has been shown to halt the cell cycle progression of various normal, nontransformed cell types in G₁, most virus transformed or tumor cells are unaffected in G₁ but arrest in G₂ phase. SSP has also been observed to increase the appearance of cells with higher DNA content, suggestive of endoreduplication, in cultures of tumor cells. Using multivariate flow cytometry (DNA content vs. expression of cyclin B, nucleolar p120 protein, or protein reactive with Ki-67 antibody) which makes it possible to discriminate cells with identical DNA content but at different phases of the cycle, we have studied the cell cycle progression of human lymphocytic leukemic MOLT-4 cells in the presence of 0.1 μM SSP.MOLT-4 cells did not arrest in G₁ or G₂ phase in the presence of the inhibitor. Rather, they failed to undergo cytokinesis, entering G₁ phase at higher DNA ploidy (tetraploidy; G_1T), and then progressed through S_T (rereplication) into G_2T and M_T. The rates of entrance to G₂ and G_2T were essentially identical, indicating that the rates of cell progression through S and S_T as well as through G₂ and G_2T, respectively, were similar. Cells entrance to mitosis and mitotic chromatin condensation were also similar at the diploid and tetraploid DNA content level and were unaffected by 0.1 μM SSP. No evidence of growth imbalance (altered protein or RNA to DNA ratio) was observed in the case of tetraploid cells. The data show that, in the case of MOLT-4 cells, all events associated with the chromosome or DNA cycle were unaffected by SSP; the only target of the inhibitor appears to be kinase(s) controlling cytokinesis. © 1994 Wiley-Liss, Inc.     

Reversible accumulation of plant suspension cell cultures in g(1) phase and subsequent synchronous traverse of the cell cycle

The induction of DNA synthesis in Datura innoxia Mill. cell cultures was determined by flow cytometry. A large fraction of the total population of cells traversed the cell cycle in synchrony when exposed to fresh medium. One hour after transfer to fresh medium, 37% of the cells were found in the process of DNA synthesis. After 24 hours of culture, 66% of the cells had accumulated in G₂ phase, and underwent cell division simultaneously. Only 10% of the cells remained in G₀ or G₁. Transfer of cells into a medium, 80% (v/v) of which was conditioned by a sister culture for 2 days, was adequate to inhibit this simultaneous traverse of the cell cycle. A large proportion of dividing cells could be arrested at the G₀ + G₁/S boundary by exposure to 10 millimolar hydroxyurea (HU) for 12 to 24 hours. Inhibition of DNA synthesis by HU was reversible, and when resuspended into fresh culture medium synchronized cells resumed the cell cycle. Consequently, a large fraction of the cell population could be obtained in the G₂ phase. However, reversal of G₁ arrested cells was not complete and a fraction of cells did not initiate DNA synthesis. Seventy-four percent of the cells simultaneously reached 4C DNA content whereas the frequency of cells which remained in G₀ + G₁ phase was approximately 17%. Incorporation of radioactive precursors into DNA and proteins identified a population of nondividing cells which represents the fraction of cells in G₀. The frequency of cells entering G₀ was 11% at each generation. Our results indicate that almost 100% of the population of dividing cells synchronously traversed the cell cycle following suspension in fresh medium.     

Anticancer effect of Tamarix gallica extracts on human colon cancer cells involves Erk1/2 and p38 action on G2/M cell cycle arrest

Taking into account that oxidative stress is among the factors causing cancer-related death; chemoprevention which consists in using antioxidant substances such as phenolics could prevent cancer formation and progression. In the present study, phenolic contents and antioxidant activities of methanolic extracts from the halophyte Tamarix gallica shoots were determined. Moreover, the anticancer effect of this species on human colon cancer cells and the likely underlying mechanisms were also investigated. Shoot extracts showed an appreciable total phenolic content (85 mg GAE/g DW) and a high antioxidant activity (IC₅₀ = 3.3 μg/ml for DPPH test). At 50 and 100 μg/ml, shoot, leaf, and flower extracts significantly inhibited Caco-2 cell growth. For instance, almost all plant part extracts inhibited cell growth by 62 % at the concentration 100 μg/ml. DAPI staining results revealed that these extracts decrease DNA synthesis and confirm their effect on Caco-2 cells proliferation, principally at 100 μg/ml. More importantly, cell mitosis was arrested at G₂/M phase. The changes in the cell-cycle-associated proteins (cyclin B1, p38, Erk1/2, Chk1, and Chk2) are correlated with the changes in cell cycle distribution. Taken together, our data suggest that T. gallica is a promising candidate species to be used as a source of anticancer biomolecules.     

A DELAY IN THE G2 PERIOD OF CULTURED HUMAN LEUCOCYTES AFTER TREATMENT WITH RUBIDOMYCIN (DAUNOMYCIN)

Human leucocytes were cultured for 3 days at 37°C, and during this time treated with rubidomycin (also known as daunomycin) for periods up to 48 hr. The effects of this treatment were studied by examining mitotic indices, uptake of ³H-thymidine, and patterns of DNA content (measured by microdensitometry on Feulgen-stained cells). A low concentration of rubidomycin (0.1 μg/ml) caused accumulation of cells in the G₂ period, which in turn resulted in a decrease in the mitotic index. A secondary effect was a slight drop in ³H-thymidine uptake after 12 hr. Higher doses (up to 10 μg rubidomycin per ml) caused an inhibition of DNA synthesis, with accumulation of unlabelled cells between G₂ and G₂. The probable mode of action of rubidomycin, as presented by earlier authors, is the intrusion of the drug molecule between DNA strands, forming a complex with DNA, and hindering its normal folding. This is discussed with respect to the present findings.     

THE MECHANISM OF 5-AMINOURACIL-INDUCED SYNCHRONY OF CELL DIVISION IN VI CIA FABA ROOT MERISTEMS

Cessation of mitosis was brought about in Vicia faba roots incubated for 24 hours in the thymine analogue, 5-aminouracil. Recovery of mitotic activity began 8 hours after removal from 5-aminouracil and reached a peak at 15 hours. If colchicine was added 4 hours before the peak of mitoses, up to 80 per cent of all cells accumulated in mitotic division stages. By use of single and double labeling techniques, it was shown that synchrony of cell divisions resulted from depression in the rate of DNA synthesis by 5-aminouracil, which brought about an accumulation of cells in the S phase of the cell cycle. Treatment with 5-aminouracil may have also caused a delay in the rate of exit of cells from the G₂ period. It appeared to have no effect on the duration of the G₁ period. When roots were removed from 5-aminouracil, DNA synthesis resumed in all cells in the S phase. Although thymidine antagonized the effects of 5-aminouracil, an exogenous supply of it was not necessary for the resumption of DNA synthesis, as shown by incorporation studies with tritiated deoxycytidine.     

Density dependent regulation of growth in suspension cultures of L-929 cells

Suspension cultures of L-929 fibroblasts grown to densities of 6 to 10 × 10⁶ cells/ml through daily centrifugation and resuspension in fresh media, have been maintained for periods up to five months without change in viability or cell size. DNA synthesis and mitosis in these cultures is limited to 5% of the cells per day, a fraction very nearly equal to the fraction of cells rendered nonviable, most likely during the manipulations associated with medium renewal. The kinetics of the flow of cells into the S and M periods following (a) renewal of the medium and (b) dilution of the high density cultures, suggest that the large majority of the cells are in a G₀ or early G₁ phase, resuming growth readily in response to decreased cell density. This is further indicated by the sequence of the marked shifts occurring in the cell volume distribution spectrum of the high density cultures after dilution. Long term, steady state regulation of growth with retention of intact viability was thus demonstrated in the case of a long established aneuploid cell line. The fact that this occurs in suspension but not in attached cultures, supports the concept that impairment of growth control in such cells affects predominantly regulatory mechanisms located at the cell surface rather than those concerned with intracellular synthesis and metabolism.     

Effects of chlorambucil on human chromosomes

No significant amount of chromosomal damage was found in the 48-h cultures of lymphocytes of 18 patients who had been treated with the bifunctional alkylating agent chlorambucil (CBC). However, there was suggestive evidence of chromatid damage (i.e. of types attributable to damage during or after DNA synthesis in the cell cycle). In marrow cells of 3 patients given a single large dose of chlorambucil (equivalent to 2 days' normal treatment) there was also suggestive evidence of induced chromatide-type damage.Extensive series of in vitro experiments yielded evidence that (a) exposure of human lymphocytes over the whole period of culture showed chromatid-type damage; (b) this damage increased sharply from concentrations of 0.5 μg/ml to3.0 μg/ml; (c) although chromatide-type damage always predominated, there was suggestive evidence also of chromosome-type aberrations attributable to damage occuring in the G₀/G₁ period, although some or all of this could be attributed to “derived” chromatid damage; (d) even if lymphocytes were only exposed during the G₀ or G₁ periods of the cycle, damage was found in the subsequent metaphases and it was almost entirely of the chromatid type; (e) much more damage occurred in lymphocytes exposed for varying periods to the drugs after stimulation by phytohaemagglutinins than in those exposed in whole blood, or in medium before stimulation; (f) damaged occurred in lymphocytes exposed to the drug while in S but not exposed only when in G₂; (g) no evidence was found that unschaduled DNA synthesis during G₀ or G₁ was induced by the drug; (h) there appeared to be no delay caused by the drug in the time at which cells reached the first “S” phase in culture but there was some evidence consistent with prolongation of “S” in cells exposed in culture; (i) there was evidence that CBC alone could stimulate lymphocyte tto DNA synthesis, and that a few cells proceeded in the cycle to prophase, or even metaphase. However, there was a considerable amount of cell-killing during CBC-stimulated DNA synthesis.