Inhibition of cellular transition from G1-resting to G1-prereplicative phase by aminonucleoside or puromycin

Summary Human embryonic lung fibroblasts (IMR-90 and WI-38) were arrested in the G₁ phase of the cell cycle by serum deprivation and high population density. Within 1 hr after the addition of medium containing fresh serum, these cells showed an increase in rRNA synthesis. The inclusion of 100 μg per ml aminonucleoside of puromycin (AMS) in the fresh medium eliminated the serum stimulation of rRNA synthesis and prevented the cells from making the G₁-resting phase to G₁-prereplicative phase transition. AMS also prevented the synthesis of HnRNA normally found within 10 hr after serum stimulation. Serum-stimulated RNA synthesis in starved, SV-40 transformed fibroblasts (WI-38-VA-13 cells) was inhibited, but not completely prevented, by AMS indicating that transformed cells may produce specific RNA's that are not AMS-sensitive and that may be responsible for the failure of transformed cells to be arrested in G₁. This work was supported by PHS Research Grant CA19750-02 from the National Cancer Institute. These results were reported previously in a preliminary form (7).     

REGULATION OF INITIATION OF DNA SYNTHESIS IN CHINESE HAMSTER CELLS : II. Induction of DNA Synthesis and Cell Division by Isoleucine and Glutamine in G1-Arrested Cells in Suspension Culture

Suspension cultures of Chinese hamster cells (line CHO), which had stopped dividing and were arrested in G₁ following growth to high cell concentrations in F-10 medium, could be induced to reinitiate DNA synthesis and to divide in synchrony upon addition of the appropriate amounts of isoleucine and glutamine. Both amino acids were required to initiate resumption of cell-cycle traverse. Deficiencies in other amino acids contained in F-10 medium did not result in accumulation of cells in G₁, indicating a specific action produced by limiting quantities of isoleucine and glutamine. In the presence of sufficient glutamine, approximately 2 x 10^-6 M isoleucine was required for all cells to initiate DNA synthesis in a population initially containing 1.5 x 10⁵ cells/ml. Under similar conditions, about 4 x 10^-6 M isoleucine was required for all G₁-arrested cells to progress through cell division. In contrast, 1 x 10^-4 M glutamine was necessary for maximum initiation of DNA synthesis in G₁ cells, along with sufficient isoleucine. A technique for rapid production of G₁-arrested cells is described in which cells from an exponentially growing population placed in F-10 medium deficient in both isoleucine and glutamine or isoleucine alone accumulated in G₁ after 30 hr.     

THE SYNTHESIS OF ACIDIC CHROMOSOMAL PROTEINS DURING THE CELL CYCLE OF HELA S-3 CELLS : I. The Accelerated Accumulation of Acidic Residual Nuclear Protein before the Initiation of DNA Replication

The synthesis and accumulation of acidic proteins in the tightly bound residual nuclear fraction goes on throughout the cell cycle of continuously dividing populations of HeLa S-3 cells; however, during late G₁ there is an increased rate of synthesis and accumulation of these proteins which precedes the onset of DNA synthesis. Unlike that of the histones, whose synthesis is tightly coupled to DNA replication, the synthesis of acidic residual nuclear proteins is insensitive to inhibitors of DNA synthesis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of acidic residual nuclear proteins shows different profiles during the G₁, S, and G₂ phases of the cell cycle. These results suggest that, in contrast to histones whose synthesis appears to be highly regulated, the acidic residual proteins may have a regulatory function in the control of cell proliferation in continuously dividing mammalian cells.     

Stimulation of DNA synthesis and cell division in a chemically defined medium: Effect of Epidermal Growth Factor,Insulin and Vitamin B12 on resting cultures of 3T6 cells

Addition of Epidermal Growth Factor, Insulin and Vitamin B₁₂ in completely serum free medium to cultures of 3T6 cells arrested in the $\text{G}{}_1\text{G}{}_0$ phase of the cell cycle stimulates DNA synthesis in 80–90% of the cell population. Cell division occurs 48–72 hours after factor addition. Because the peptides are active at low levels and interact synergistically, this model system offers a powerful tool for elucidating mechanisms of growth regulation which might have a physiological relevance.     

DNA synthesis and cell cycle progression of synchronized L-cells after irradiation in various phases of the cell cycle

Summary The varying sensitivity to radiation in the different phases of the cell cycle was investigated using L-929 cells of the mouse. The cells were synchronized by mechanical selection of mitotic cells. The synchronous populations were X-irradiated with a single dose of 10 Gy in the middle of the G₁-phase, at the G₁/S-transition or in the middle of the S-phase, respectively. The radiation effect was determined in 2 h intervals a) by¹⁴C-TdR incorporation (IT) into the DNA, b) by autoradiography (AR), c) by flow cytometry (FCM). The incorporation rate decreased in all three cases, but the reasons appeared to be different, as can be derived from FCM and AR data: After irradiation in G₁, a fraction of cells was prevented from entering S-phase, after irradiation at G₁/S a proportion of cells was blocked in the S-phase, and after irradiation in S, DNA synthesis rate was reduced. As a consequence of these effects, the mean transition time through S-phase increased. The G₂ blocks, obtained after irradiation at the three stages of the cycle were also different: Cells irradiated in G₁ are partly released from the block after 10 h. Irradiation at G₁/S caused a persisting accumulation of 50% of the cells in G₂, and for irradiation in S more than 80% of the cells were arrested in G₂.     

Derepression of the cell cycle by starvation is involved in the induction of tobacco pollen embryogenesis

Summary Microspectrophotometry following Feulgen staining and autoradiography following (³H)-thymidine labelling were used to study cell-cycle events during pollen development in tobacco (Nicotiana tabacum L.). During normal gametophytic pollen development in the anther and in vitro the generative nucleus passes through the S phase to the G₂ phase soon after microspore mitosis, while the vegetative nucleus remains arrested in G₁ (=G₀). During embryogenie induction by an in vitro starvation treatment of immature pollen ongoing DNA replication in the generative nucleus is completed and followed by DNA replication in the vegetative cell in a large fraction of the pollen grains. Addition of the DNA replication inhibitor hydroxyurea to the starvation medium postpones S phase entry until the pollen is transferred to a rich medium and does not affect embryo formation. These results demonstrate that one of the crucial events of embryogenic induction is the derepression of the G₁ arrest in the cell cycle of the vegetative cell.     

A METHOD FOR COMPARING EFFECTS OF DIFFERENT SYNCHRONIZING PROTOCOLS ON MAMMALIAN CELL CYCLE TRAVERSE : The Traverse Perturbation Index

After treatment of Chinese hamster cells (line CHO) with various protocols for synchrony induction, the subsequent ability of cells to traverse the cell cycle (i e., to perform, an essential cell cycle process) has been determined by measurement of the DNA distribution pattern among cells in large populations with the Los Alamos flow microfluorometer In the cultures prepared by the various synchronizing techniques the vast majority of cells traversed the cell cycle in a normal fashion; however, in all cultures examined there remained small subpopulations which, though remaining viable for several days, could not carry out normal traverse. After reversible inhibition of DNA synthesis by means of a double-thymidine blockade, approximately 17% of the cells were unable to complete genome replication. After reversal of G₁ arrest resulting from cultivation of cells in isoleucine-deficient medium, 12 4% of the cells commenced synthesis of DNA but were unable to complete the S phase. Cells prepared by mitotic selection yielded a subpopulation (5 5% of the total cells) with a G₁ DNA content which remained viable but noncycling for at least 5 days. We propose a term "traverse perturbation index" which is defined as the fraction of cells converted to a noncycle-traversing state as the result of experimental manipulation. A knowledge of the perturbation index will allow direct comparison of effects on cell cycle traverse of various synchrony-induction protocols     

Stimulation of WI-38 cell cycle transit: Effect of serum concentration and cell density

Flow microfluorometry has been used to characterize the effects of serum concentration and cell density on the initiation of cell cycle transit of stationary phase (G₀) human diploid fibroblasts (strain WI-38). The concentration of serum used to stimulate these cultures had no effect on the time cells began appearing in S (the DNA synthetic period), nor on the synchrony with which they moved around the cell cycle. However, as the serum concentration increased, the fraction of the stationary phase population released from G₀ increased. Cell density modulated the ability of serum to stimulate cell cycle traverse. For example, at a cell density of 1.81 × 10⁴ cells/cm², 78% of the population was sensitive to serum stimulation; whereas, when the density was increased to 7.25 × 10⁴ cells/cm², only 27% of the population could be stimulated. This effect of cell density on the serum response is not simply the result of changing the ratio of serum concentration to cell density, but appears to reflect a true modulation of the population's sensitivity to serum stimulation. These results are consistent with the interpretation that the primary action of serum is to determine the transition of cells from a non-cycling G₀ state to a cycling state and that cell density determines the proportion of the population capable of undergoing this transition.     

EXPERIMENTAL CONTROL OF DNA SYNTHESIZING AND DIVIDING CELLS IN EXCISED ROOT TIPS OF PISUM

The number of dividing and DNA-synthesizing cells in excised pea roots can be regulated by eliminating the carbohydrate normally supplied in the culture medium. When the excised roots were allowed to remain for 24 hr in a medium lacking carbohydrate, the number of mitotic figures and tritiated thymidine (H³-T) labeled cells was reduced almost to zero. After an additional 24 hr in the incomplete culture medium, 15% of the interphase cells were H³-T labeled, the percentage of the cells that were dividing never exceeded 1.4, and 30% of these were H³-T labeled. When the roots remained in the deficient medium for 72 hr, neither cell division nor cells synthesizing DNA were observed. Upon addition of 2% sucrose, cell division and DNA synthesis were resumed in the roots that were maintained for 24 or 72 hr without an exogenous carbohydrate supply. It has been hypothesized that some proliferative systems consist of two cellular subpopulations which selectively stop or remain in either the pre-DNA synthetic (G₁) or post-DNA synthetic (G₂) periods of the mitotic cycle. The addition of sucrose, H³-T, and 5-aminouracil to the medium, after the roots had been maintained for 24 hr without a carbohydrate, indicated that most of the proliferative cells in the roots had accumulated in either G₁, a quasi-G₁ condition, i.e., DNA synthesis stopped sometime before completion, or G₂ periods of interphase; the majority, however, were in G₁ or quasi-G₁ conditions. The results suggested that DNA synthesis (S period) and mitosis or the onset of these processes have the highest metabolic requirements in the mitotic cycle and that G₁ and G₂ were the most probable states for proliferative cells in a meristem with a low metabolic level.     

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

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

Cell cycle arrest by prostaglandin A1 at the G1/S phase interface with up-regulation of oncogenes in S-49 cyc− cells

Our previous studies have implied that prostaglandins inhibit cell growth independent of cAMP. Recent reports, however, have suggested that prostaglandin arrest of the cell cycle may be mediated through protein kinase A. In this report, in order to eliminate the role of c-AMP in prostaglandin mediated cell cycle arrest, we use the-49 lymphoma variant (cyc^?) cells that lack adenylate cyclase activity. We demonstrate that dimethyl prostaglandin A₁ (dmPGA₁) inhibits DNA synthesis and cell growth in cyc^? cells. DNA synthesis is inhibited 42% by dmPGA₁ (50 μM) despite the fact that this cell line lacks cellular components needed for cAMP generation. The ability to decrease DNA synthesis depends upon the specific prostaglandin structure with the most effective form possessing the α,β unsaturated ketone ring. Dimethyl PGA₁ is most effective in inhibiting DNA synthesis in cyc^? cells, with prostaglandins PGE₁ and PGB₁ being less potent inhibitors of DNA synthesis. DmPGE₂ caused a significant stimulation of DNA synthesis. S-49 cyc^- variant cells exposed to (30–50 μm) dmPGA₁, arrested in the G₁ phase of the cell cycle within 24 h. This growth arrest was reversed when the prostaglandin was removed from the cultured cells; growth resumed within hours showing that this treatment is not toxic. The S-49 cyc^? cells were chosen not only for their lack of adenylate cyclase activity, but also because their cell cycle has been extensively studied and time requirements for G₁, S, G₂, and M phases are known. Within hours after prostaglandin removal the cells resume active DNA synthesis, and cell number doubles within 15 h suggesting rapid entry into S-phase DNA synthesis from the G₁ cell cycle block. The S-49 cyc^? cells are known to have a G₁/S boundary through M phase transition time of 14.8 h, making the location of the prostaglandin cell cycle arrest at or very near the G₁/S interface. The oncogenes, c-fos and c-myc which are normally expressed during G₁ in proliferating cells have a 2–3 fold enhanced expression in prostaglandin G₁ arrested cells. These data using the S-49 variants demonstrate that dmPGA₁ inhibits DNA synthesis and arrests the cell cycle independent of cAMP-mediated effects. The prostaglandin arrested cells maintain the gene expression of a G₁ synchronous cell which suggests a unique molecular mechanism for prostaglandin action in arresting cell growth. These properties indicate that this compound may be an effective tool to study molecular mechanisms of regulation of the cell cycle.     

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.     

DNA synthesis and proliferation of human lymphocytes in vitro: III. Fate of cycling cells in aging cultures of phytohemagglutinin stimulated human lymphocytes

There are few data available on cell cycle events that occur when proliferation of normal cells in culture is curtailed due to “natural aging” of the culture conditions. Stathmokinetic and cytofluorometry studies were performed on PHA-stimulated human lymphocyte cultures for eight consecutive days. Cell proliferation peaked on day 5 and then gradually decreased. Percent labeled mitosis curves performed each day demonstrated that, for those cells which progressed to mitosis, the cell cycle time remained constant at 18 ± 1 hour throughout the entire period of culture. However when the fate of all cells pulse-labeled with ³H-thymidine (S phase cells) was followed daily, only 64 ± 5% of labeled cells reached mitosis on day 3 and <20% on day 6. When the growth fraction was estimated by standard methods (with the labeling index) and used to predict future cell counts in the culture, proliferation was greatly overestimated; but after correcting the growth fraction for labeled cells not reaching mitosis, proliferation was accurately predicted by a newly derived “dividing fraction.” Flow cytofluorometry confirmed accumulation of cells in S and G₂ + M phases, and mitotic indices ruled out accumulation in M phase. Assessment of non-viable cells with cytofluorometry demonstrated that death occurred in all phases of the cell cycle. We conclude that with increasing age of culture, an increased fraction of cycling PHA-stimulated lymphocytes fail to progress all the way to mitosis and are arrested in S or G₂ phases. These observations provide evidence against the existence of a specific “restriction point” in G₁ or at the G₁/S interface in aging proliferating human lymphocyte cultures, but it remains to be determined whether cells arrested in S or G₂ phases retain the capacity to complete the cell cycle in more favorable culture environments.     

Cell-Cycle-Dependent and -Independent Damage to Rat Haemopoiesis By Hydroxyurea

The generally accepted cell-killing effect of hydroxyurea (HU) on S-phase cells, as well as its potential to arrest cells at the G₁/S boundary, hardly explain its benefit for application in human chronic myelogenous leukaemia. Studies were therefore performed in rat haemopoiesis in order to quantify the cell-killing effect on various phases of the cell cycle. For this purpose, the [³H]thymidine ([³H]TdR) labelling index and the specific activity of [³H]TdR in the DNA-synthesizing fraction of cells were determined after a non-cytoreductive dose of 25 mg/kg HU, as well as a medium cytoreductive dose of 100 mg/kg. Furthermore, flow cytometric DNA histograms and absolute as well as differential cell counts of femoral bone marrow were performed after 100 mg/kg HU. The results indicate a predominant cell kill in G₁ encompassing almost all 2c cells in the proliferative pool, while the S-phase fraction is not even reduced to half its initial value. the specific activity of [³H]TdR in cells synthesizing DNA, as well as the labelling index after HU show an initial dip and a tendency to recovery, as has been observed in many other cell systems. Instead of a complete restoration, however, there is a second depression of these parameters lasting for at least one cell cycle. the results are interpreted as a partly cell-cycle-dependent and partly independent action of HU in this cell system. the independent component may be attributed to the repeatedly described direct interference of HU with DNA. In rat haemopoiesis, therefore, this direct effect of HU on the DNA strands appears to be much more pronounced than in cell-culture systems and other mammalian tissues. In view of these findings, some caution should be taken in using HU for the determination of the S-phase fraction by way of a suicide experiment.     

Unbalanced growth and cell death in HeLa S3 cultures treated with DNA synthesis inhibitors

Flow cytometry indicated that significant amounts of dsRNA were accumulated in HeLa S3 cells blocked at or near G₁/S boundary by hydroxyurea (HU) or excess thymidine (TdR). The dsRNA/DNA ratio increased in these cells in a manner characteristic of unbalanced cell growth. In HU-treated cells, dsRNA content was maximal 16 hours after addition of the drug and did not change significantly during the next 24 hours. The DNA content in blocked cells increased by 10%. Cell viability assessed by colony formation in soft agar decreased exponentially in HU-treated cultures after 16 hours of incubation. Correlation between loss of cell viability and rate of cell proliferation after removal of HU was observed, as determined by cell count and analysis of cell cycle progression. In TdR-treated cultures cells slowly progressed into mid S-phase during 40 hours and dsRNA accumulation continued during this period. Cell viability was not significantly affected by treatment with excess TdR, indicating that unbalanced growth per se, as measured by dsRNA accumulation, is not lethal for the cells. After reversal of DNA synthesis inhibition by removal of the drug, cells treated with HU for 16 hours or TdR for 16–24 hours promptly progressed through the cell cycle. This progression was accompanied by accumulation of significant amounts of dsRNA. As a result, cells in G₂ phase had a very high dsRNA content leading to retention of the unbalanced condition (increased dsRNA/DNA ratio) in the daughter cells. It is suggested that dsRNA accumulation in the cell is controlled to a certain degree by cell progression through the S phase. This type of control, evidently, was reflected in limited dsRNA accumulation in the cells blocked at or near G₁/S border, in continuous dsRNA accumulation in the cells slowly progressing through S phase, and in accumulation of large amounts of dsRNA after renewal of progression through the S phase.     

Reduced inhibition of DNA synthesis and G2 arrest during the cell cycle of resistant HeLa cells in response tocis-diamminedichloroplatinum

The influence of cisplatin, an anticancer agent, on DNA synthesis and cell cycle progression of a cisplatin-resistant cell line was investigated. Cell cycle analysis using flow cytometry showed that cytotoxic concentrations of cisplatin caused a transient inhibition of parental HeLa cells at S phase, followed by accumulation at G₂ phase. In contrast, the resistant cells progressed through the cell cycle without being affected by the same treatment. However, cell cycle distributions were the same in the resistant and the parental cells at IC₅₀, the drug concentration inhibiting cell growth by 50%. Studies using a [³H]thymidine incorporation technique also demonstrated a transient inhibition of DNA synthesis in HeLa cells by cisplatin; such inhibition was greatly reduced in the resistant cells. These data argue for the hypothesis that the inhibition of DNA synthesis is important in determining cisplatin-induced cytotoxicity. In addition, the accumulation of cells at G₀/G₁ by serum starvation was not effective in the resistant cells compared to the parental cells, suggesting that the control of cell cycle exiting is also altered in the resistant cells. Taken together, these results support the notion that alterations in cell cycle control, in particular G₂ arrest, are important in determining the sensitivity or resistance of mammalian cells to cisplatin and may have a role in clinical protocols.     

Differential effects of ACTH or 8-Br-cAMP on growth and replication in a functional adrenal tumor cell line

The effects of ACTH and 8-Br-cAMP on growth and replication of a functional mouse adrenal tumor cell line (Y-1) were investigated. ACTH and 8-Br-cAMP both inhibited DNA synthesis and replication when added to randomly growing cell cultures. ACTH addition and serum deprivation each arrested cells in G₁; an additional point of arrest in G₂ occurred with 8-Br-cAMP. Cells whose growth was arrested in G₁ by ACTH had a significantly larger volume and protein and RNA content compared to cells arrested in G₁ by serum deprivation. When ACTH or 8-Br-cAMP was added with serum to cells arrested by serum deprivation, the wave of DNA synthesis and cell division seen with serum was abolished. ACTH and 8-Br-cAMP had no effect on the serum-induced increases in protein and RNA content, rates of leucine incorporation into protein and uridine incorporation into RNA, and RNA polymerase I activity observed in cells during the pre-replicative period. Partial inhibition of the serum-induced increase in uridine transport occurred. ACTH and cAMP do not appear to inhibit replication by generalized negative pleiotypic effects but rather to inhibit the initiation of DNA synthesis more specifically. The ACTH-arrested Y-1 cell resembles an in vivo hypertrophied adrenal cortical cell.     

Autocrine regulation of cell cycle progression in normal human keratinocytes

Summary Removal of competence factors insulin and pituitary extract from the culture medium, concomitant with the addition of picomolar concentrations of the late-G₁ inhibitor transforming growth factor-beta, effectively arrested cell cycle progression of normal human keratinocytes prior to their entry into the DNA synthesis phase; arrest continued for a minimum of 36 h following removal of unbound inhibitor and subsequent addition of factor-deficient medium. To demonstrate the reversibility of transforming growth factor-beta-induced arrest, two dissimilar cell populations were recruited to synthesize DNA in a predictable and reproducible manner; whereas the reinstatement of omitted competence factors induced noncycling cells to begin synthesizing DNA within 24 h, addition of keratinocyte-conditioned medium prompted an immediate progression of late-G₁ cells into S phase. Studies to determine the extent that autocrine signaling regulates cell cycle progression revealed that nontransformed keratinocytes produce an endogenous factor required for DNA replication and that production of this progression factor required competence factors insulin and pituitary extract. Keratinocyte progression factor recruited late-G₁ cells into S phase within 1–2 h, reversed transforming growth factor-beta-induced arrest in the presence of bound inhibitor, and elicited a calcium mobilization response consistent with receptor-mediated signaling. Hence, these studies demonstrate that G₁ progression of nontransformed keratinocytes into S phase requires an endogenous progression factor and suggest that this factor may direct G₁ progression by modulating the activity of a calcium-dependent kinase.     

Conjugation Between G1 and G2 Phase Cells in Paramecium tetraurelia1

Cells of Paramecium tetraurelia, stock hr^d, cultured in a micro-capillary containing 1 μl fresh culture medium, expressed mating activity through the whole cell cycle. Mating-reactive G₂ phase cells can conjugate with cells of other phases. The G₂ phase cells, which have double (4C) the normal micronuclear DNA content, undergo pre-meiotic DNA synthesis when conjugated with G₁ phase cells. The micronucleus of the progeny from the cross between a G₁ and a G₂ cell becomes triploid.     

Sulfhydryl groups during the S phase: comparison of cells from G 1 , plateau-phase G 1 , and G 0

The non-protein sulfhydryl (NPSH) content of cells moving into S from G₁, plateau phase G₁, and G₀ was measured. Chinese hamster ovary (CHO) cells accumulated in G₁ by growth into plateau phase contain only one-fourth the NPSH concentration of cycling C₁ cells or G₁ cells accumulated by brief growth in isoleucine-deficient medium. Upon dilution of plateau cultures with fresh medium, cellular NPSH content increases rapidly, reaching the same level as that in cycling cells within four hours. This increase is prevented by cycloheximide but not by actinomycin D or hydroxyurea. Neither CHO cells cycling in vitro nor salivary gland G₀ cells stimulated with isoproterenol in vivo show significant changes in intracellular NPSH concentrations during S phase. This suggests that the concentration of intracellular NPSH (glutathione) remains constant during the cell cycle except when cells are grown to plateau phase in exhausted or deficient medium, in which case normal degradation exceeds synthesis and the gross level falls until fresh medium is provided and synthesis, apparently on preexisting RNA templates, accelerates.