Regulation of mitosis onset and thymidine kinase activity during the cell cycle of Physarum polycephalum plasmodia: effect of hydroxyurea

The effects of hydroxyurea have been investigated on three events of the cell cycle, S-phase, mitosis, and the cyclic synthesis of thymidine kinase, in the synchronous plasmodium of the myxomycete Physarum. DNA synthesis was slowed down with limited action on other macromolecular syntheses and any increase of thymidine kinase that had already been triggered was indistinguishable from that of the control. When DNA synthesis was inhibited, the onset of the following cyclic increase of thymidine kinase synthesis occurred at the same time as in the control, but mitosis was delayed in a very early prophase stage. The arrest of thymidine kinase synthesis occurred after completion of the delayed mitosis. All these effects were suppressed when the action of hydroxyurea was prevented by the addition, to the medium, of the four deoxyribonucleosides. These observations show that (1). The blockage of S-phase does not prevent the nuclei from entering a very early prophase stage but does prevent them from proceeding through metaphase. (2) The transient blockage of DNA synthesis does not perturb the normal timing of the triggering of thymidine kinase synthesis. (3) The signal which triggers the arrest of thymidine kinase synthesis is postmitotic but does not require extensive DNA synthesis. The effect of hydroxyurea is not limited to an inhibition of S-phase. The blockage of DNA replication also led to the dissociation of the normal coordination between two other events of the cell cycle, mitosis and thymidine kinase synthesis. This observation could have strong implications in cell synchronization with chemical agents.     

Regulation of mitosis onset and thymidine kinase synthesis during the cell cycle of Physarum polycephalum: action of aphidicolin

In Physarum polycephalum (Myxomycetes) aphidicolin has been found to delay metaphase onset when applied to synchronous plasmodia 3 h before control metaphase. In contrast to the action of temperature shifts, aphidicolin treatment did not delay the initiation of the increase of thymidine kinase synthesis (EC 2.7.1.21, ATP-thymidine 5' phosphotransferase) and the decrease of the synthesis of thymidine kinase occurred normally after completion of mitosis in presence of aphidicolin. The amount of thymidine kinase synthesized was larger for aphidicolin treated plasmodia than in the control due to both a longer period of increased synthesis and a higher maximum rate of synthesis. These results were interpreted by postulating the presence of two regulatory pathways. The first one acting on the increase of the synthesis of thymidine kinase and on mitosis onset was sensitive to temperature shifts from 22 to 32 degrees C. The second one acting on mitosis onset only was sensitive to aphidicolin.     

Enzyme regulation during the synchronous nuclear cycle of Physarum polycephalum: Effects of methotrexate and hydroxyurea on thymidine kinase and deoxycytidine kinase

Specific enzyme activities of thymidine kinase (TK) and deoxy-cytidine kinase (dCK) increase sharply at the onset of synchronous mitosis in macroplasmodia of Physarum polycephalum. They reach a maximum in early S-phase (Physarum lacks a G1 period) and decline to a minimum in late G2. Partial inhibition of DNA synthesis with methotrexate (MTX) or hydroxyurea (HU) retards the onset of the next mitosis and provokes a superinduction of both enzymes, with dCK responding stronger than TK. The temporal pattern observed suggests that the drugs interfere with the postmitotic down-regulation of enzyme expression, possibly due to alterations of the chromatin structure. Moderate inhibition of DNA synthesis still permits the appearance of (delayed) mitoses associated with peaks of enzyme activity at elevated levels. On the other hand, stronger inhibition completely suppresses the onset of mitosis and keeps the enzyme activities at an elevated level without further oscillations. The timing mechanism of periodic enzyme induction therefore appears to be functionally linked to the mitotic signal and does not persist under a stringent DNA block.     

LIMITED DNA SYNTHESIS IN THE ABSENCE OF PROTEIN SYNTHESIS IN PHYSARUM POLYCEPHALUM

Actidione (cycloheximide), an antibiotic inhibitor of protein synthesis, blocked the incorporation of leucine and lysine during the S phase of Physarum polycephalum. Actidione added during the early prophase period in which mitosis is blocked totally inhibited the initiation of DNA synthesis. Actidione treatment in late prophase, which permitted mitosis in the absence of protein synthesis, permitted initiation of a round of DNA replication making up between 20 and 30% of the unreplicated nuclear DNA. Actidione treatment during the S phase permitted a round of replication similar to the effect at the beginning of S. The DNA synthesized in the presence of actidione was replicated semiconservatively and was stable through at least the mitosis following antibiotic removal. Experiments in which fluorodeoxyuridine inhibition was followed by thymidine reversal in the presence of actidione suggest that the early rounds of DNA replication must be completed before later rounds are initiated.     

The Pds1 anaphase inhibitor and Mec1 kinase define distinct checkpoints coupling S phase with mitosis in budding yeast

In most eukaryotic cells, DNA replication is confined to S phase of the cell cycle [1]. During this interval, S-phase checkpoint controls restrain mitosis until replication is complete [2]. In budding yeast, the anaphase inhibitor Pds1p has been associated with the checkpoint arrest of mitosis when DNA is damaged or when mitotic spindles have formed aberrantly [3] [4], but not when DNA replication is blocked with hydroxyurea (HU). Previous studies have implicated the protein kinase Mec1p in S-phase checkpoint control [5]. Unlike mec1 mutants, pds1 mutants efficiently inhibit anaphase when replication is blocked. This does not, however, exclude an essential S-phase checkpoint function of Pds1 beyond the early S-phase arrest point of a HU block. Here, we show that Pds1p is an essential component of a previously unsuspected checkpoint control system that couples the completion of S phase with mitosis. Further, the S-phase checkpoint comprises at least two distinct pathways. A Mec1p-dependent pathway operates early in S phase, but a Pds1p-dependent pathway becomes essential part way through S phase.     

Multiple roles for protein phosphatase 1 in regulating the Xenopus early embryonic cell cycle.

Using cytostatic factor metaphase II-arrested extracts as a model system, we show that protein phosphatase 1 is regulated during early embryonic cell cycles in Xenopus. Phosphatase 1 activity peaks during interphase and decreases shortly before the onset of mitosis. A second peak of activity appears in mitosis at about the same time that cdc2 becomes active. If extracts are inhibited in S-phase with aphidicolin, then phosphatase 1 activity remains high. The activity of phosphatase 1 appears to determine the timing of exit from S-phase and entry into M-phase; inhibition of phosphatase 1 by the specific inhibitor, inhibitor 2 (Inh-2), causes premature entry into mitosis, whereas exogenously added phosphatase 1 lengthens the interphase period. Analysis of DNA synthesis in extracts treated with Inh-2, but lacking the A- and B-type cyclins, shows that phosphatase 1 is also required for the process of DNA replication. These data indicate that phosphatase 1 is a component of the signaling pathway that ensures that M-phase is not initiated until DNA synthesis is complete.     

Regulation of Claspin degradation by the ubiquitin-proteosome pathway during the cell cycle and in response to ATR-dependent checkpoint activation

Claspin is involved in ATR-dependent activation of Chk1 during DNA replication and in response to DNA damage. We show that degradation of Claspin by the ubiquitin-proteosome pathway is regulated during the cell cycle. Claspin is stabilized in S-phase but is abruptly degraded in mitosis and is absent from early G(1) cells in which the phosphorylation of Chk1 by ATR is abrogated. In response to hydroxyurea, UV or aphidicolin, Claspin is phosphorylated in the Chk1-binding domain and its protein levels are increased in an ATR-dependent manner. Thus, the Chk1 pathway is regulated through both phosphorylation of Claspin and its controlled degradation.     

Microinjected deoxynucleotides for the study of chemical inhibition of DNA synthesis.

Microinjection is shown to be a useful tool for studies of chemical inhibition of DNA synthesis: inhibitor-treated cells were injected with combinations of radioactive precursors and their uptake into DNA was monitored by autoradiography. The results obtained from inhibition by cytosinearabinoside, aphidicolin, trifluorothymidine, and fluorodeoxyuridine agreed well with the common knowledge about these drugs. Short-term (but not long-term) treatments with methotrexate were compensated by injections of thymidine-nucleotides. The effect of hydroxyurea was in part, but not fully, reversed by injection of all four deoxytriphosphates; this implies a second mechanism besides inhibition of ribonucleotide reductase. Regulation of reductase was responsible for the effect of thymidine: the enhanced dTTP caused a depletion of dCTP and dATP. Novobiocin was different from all other drugs tested, DNA polymerase or enzymes of the precursor metabolism are obviously not targets of this drug.     

Nuclear asynchrony in multinucleate rat kangaroo cells

Multinucleate (MN) cells were induced in PtK1 cells by colcemid treatment. A large percentage of cells developed nuclear asynchrony both in relation to DNA synthesis and mitosis within one cell cycle. Asynchrony could be traced even in metaphase and anaphase cells in which interphase nuclei, PCC of S-phase nuclei and less condensed prophase-like chromosomes could be observed along with normally condensed chromosomes. The occurrence of such abnormalities in these large MN cells may be explained on the basis of an uneven distribution of inducer molecules of DNA synthesis and mitosis due to cytoplasmic compartmentation. The less condensed form of all the chromosomes except chromosome 4 could be traced in asynchronous metaphase. The failure of the less condensed chromosomes to undergo complete condensation does not always appear to result from late entry of nuclei containing these chromosomes into G2 phase. It is likely that chromosome 4 carries gene(s) for chromosome condensation, as this chromosome itself never appears in a less condensed form. The inducers for chromosome condensation may not always be available at equal concentrations to all chromosomes located in separate nuclei, thus they may sometimes fail to undergo complete condensation before other nuclei reach the end of prophase, when the nuclear envelopes of all nuclei present in the cell break down simultaneously.     

Relationship between Tracheary Element Differentiation and DNA Synthesis in Single Cells Isolated from the Mesophyll of Zinnia elegans--Analysis by Inhibitors of DNA Synthesis

Effects of inhibitors of DNA synthesis on tracheary element(TE) differentiation were investigated in a culture of singlecells isolated from the mesophyll of Zinnia elegans L. cv. Canarybird. In this system, neither mitosis nor replication of thewhole genome during the S phase in the cell cycle is a prerequisitefor TE differentiation [Fukuda and Komamine (1980) Plant Physiol.65: 61, unpublished data]. Fluorouracil (FU), fluorodeoxyuridine(FUdR), mitomycin G (MC), arabinosyl cytosine (ara-C) and aphidicolin,inhibitors of DNA synthesis, prevented the incorporation of[³H]-thymidine into nucleic acid, cell division and cytodifferentiationto TE. However, neither FUdR nor aphidicolin prevented the incorporationof [14C]-leucine into protein. Thymidine reversed the inhibitoryeffect of FUdR when given simultaneously with FUdR. These resultsshow that the inhibitors of DNA synthesis prevent TE differentiationvia blockage of the synthesis of some DNA, although replicationof the whole genome during the S phase is not a prerequisitefor cytodifferentiation. The role of DNA synthesis in TE differentiationis discussed. (Received October 13, 1980; Accepted November 17, 1980)     

Chk1 and p21 cooperate to prevent apoptosis during DNA replication fork stress

Cells respond to DNA replication stress by triggering cell cycle checkpoints, repair, or death. To understand the role of the DNA damage response pathways in determining whether cells survive replication stress or become committed to death, we examined the effect of loss of these pathways on cellular response to agents that slow or arrest DNA synthesis. We show that replication inhibitors such as excess thymidine, hydroxyurea, and camptothecin are normally poor inducers of apoptosis. However, these agents become potent inducers of death in S-phase cells upon small interfering RNA-mediated depletion of the checkpoint kinase Chk1. This death response is independent of p53 and Chk2. p21-deficient cells, on the other hand, produce a more robust apoptotic response upon Chk1 depletion. p21 is normally induced only late after thymidine treatment. In Chk1-depleted cells p21 induction occurs earlier and does not require p53. Thus, Chk1 plays a primary role in the protection of cells from death induced by replication fork stress, whereas p21 mediates through its role in regulating entry into S phase. These findings are of potential importance to cancer therapy because we demonstrate that the efficacy of clinically relevant agents can be enhanced by manipulation of these signaling pathways.     

Regulation of thymidine kinase synthesis during the cell cycle of Physarum polycephalum by the heat-sensitive system which triggers mitosis and S phase

Temperature shifts from 22 to 32 °C perturb one of the systems responsible for mitosis triggering in the plasmodia of Physarum (Myxomycetes). In order to determine if the same regulatory mechanism could also be involved in some other cell cycle events, the effects of temperature shifts on the peak of thymidine kinase (EC 2.7.1.21, ATP : thymidine 5′-phosphotransferase) synthesis have been studied. At 22 °C, the increase in thymidine kinase (tdk) activity begins shortly before mitosis and is thus always associated with the end of the G2 phase, the mitosis and the beginning of the S phase. The consequences of temperature shifts depend upon their position in the cell cycle. In all cases, a peak of tdk occurs concomitantly with the 32 °C mitosis. But, when the temperature shift is applied 90-15 min before the control metaphase at 22 °C, another peak of tdk is observed at 32 °C in absence of mitosis, but at the same time as the control mitosis at 22 °C. These results indicate that the increase in the synthesis of tdk is controlled by the heat-sensitive regulatory system which plays a role in the onset of mitosis and S phase. We further suggest that the increase in the synthesis of tdk and the triggering of mitosis are both controlled by the amount of a heat-sensitive effector. But the former takes place when the amount of the effector reaches a critical value lower than the value necessary to trigger mitosis.     

Two S-phase checkpoint systems, one involving the function of both BIME and Tyr15 phosphorylation of p34cdc2, inhibit NIMA and prevent premature mitosis.

We demonstrate that there are at least two S-phase checkpoint mechanisms controlling mitosis in Aspergillus. The first responds to the rate of DNA replication and inhibits mitosis via tyrosine phosphorylation of p34cdc2. Cells unable to tyrosine phosphorylate p34cdc2 are therefore viable but are unable to tolerate low levels of hydroxyurea and prematurely enter lethal mitosis when S-phase is slowed. However, if the NIMA mitosis-promoting kinase is inactivated then non-tyrosine-phosphorylated p34cdc2 cannot promote cells prematurely into mitosis. Lack of tyrosine-phosphorylated p34cdc2 also cannot promote mitosis, or lethality, if DNA replication is arrested, demonstrating the presence of a second S-phase checkpoint mechanism over mitotic initiation which we show involves the function of BIME. In order to overcome the S-phase arrest checkpoint over mitosis it is necessary both to prevent tyrosine phosphorylation of p34cdc2 and also to inactivate BIME. Lack of tyrosine phosphorylation of p34cdc2 allows precocious expression of NIMA during S-phase arrest, and lack of BIME then allows activation of this prematurely expressed NIMA by phosphorylation. The mitosis-promoting NIMA kinase is thus a target for S-phase checkpoint controls.     

Chk1 and Wee1 kinases coordinate DNA replication, chromosome condensation, and anaphase entry

Defects in DNA replication and chromosome condensation are common phenotypes in cancer cells. A link between replication and condensation has been established, but little is known about the role of checkpoints in monitoring chromosome condensation. We investigate this function by live analysis, using the rapid division cycles in the early Drosophila embryo. We find that S-phase and topoisomerase inhibitors delay both the initiation and the rate of chromosome condensation. These cell cycle delays are mediated by the cell cycle kinases chk1 and wee1. Inhibitors that cause severe defects in chromosome condensation and congression on the metaphase plate result in delayed anaphase entry. These delays are mediated by wee1 and are not the result of spindle assembly checkpoint activation. In addition, we provide the first detailed live analysis of the direct effect of widely used anticancer agents (aclarubicin, ICRF-193, VM26, doxorubicin, camptothecin, aphidicolin, hydroxyurea, cisplatin, mechlorethamine and x-rays) on key nuclear and cytoplasmic cell cycle events.     

A cytoplasmic cell cycle controls the activity of a K+ channel in pre-implantation mouse embryos.

We previously have reported that the activity of a 240 pS K+ channel varies during the cell cycle in pre-implantation mouse embryos. In the present study, we show that: (i) the cycling of channel activity is not prevented by inhibiting protein synthesis and hence does not involve cyclin-dependent kinase 1 (cdk1)-cyclin B; and (ii) the cycling of channel activity continues in anucleate zygote fragments with a time course similar to that observed in nucleate fragments. We further demonstrate that: (i) persistent activation of the K+ channel in one-cell embryos arrested in metaphase requires the maintenance of an active cdk1-cyclin B complex; and (ii) both DNA synthesis inhibition with aphidicolin and DNA damage produced by mitomycin C prevent the down-regulation of the channel at the start of S phase by a mechanism that requires tyrosine kinase activation. Thus, the 240 pS K+ channel in these cells is controlled by a previously unsuspected cytoplasmic clock that functions independently of the well-known clock controlling the chromosomal cell cycle, but can interact with it.