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.     

Regulation of tubulin synthesis during the cell cycle in the synchronous plasmodia of Physarum polycephalum

Regulation of alpha- and beta-tubulin isotype synthesis during the cell cycle has been studied in the myxomycete Physarum polycephalum, by subjecting synchronous plasmodia to temperature shifts and pharmacological perturbations. Temperature shifts interfered with the regulation of tubulin synthesis. Inhibition of DNA synthesis prevents tubulin degradation after completion of the cell cycle (Ducommun and Wright, Eur. J. Cell Biol., 50:48-55, 1989) but did not perturb the initiation of tubulin synthesis. The constant increase of tubulin synthesis in the presence of tubulin-sequestering drugs and the decrease of tubulin synthesis during a treatment with aphidicolin in late G2 phase suggest the existence of an autoregulatory mechanism of tubulin synthesis. Moreover, the microtubule poison methyl benzimidazole carbamate dissociated synthesis of the alpha 1-tubulin isotype from the generally strictly coordinated synthesis of all tubulin isotypes during the transient interruption of mitosis. These observations show that a microtubular poison can perturb regulation of the synthesis of specific isotubulins.     

Identification and changes in activity of five thymidine kinase forms during the cell cycle of Physarum polycephalum

Five forms of thymidine kinase have been identified on isoelectric focusing gels of Physarum polycephalum supernatants. Their isoelectric points are 5.9, 6.4, 6.7, 6.9 and 7.1. All are inhibited by deoxythymidine 5′-triphosphate (dTTP). The activity of the pI 7.1 form does not change significantly during the cell cycle. The other four forms change in activity. About 1 h before metaphase the activity of the four more acidic forms is first detected. Their activity peaks during telophase, and by 1 h after metaphase there is a 50% decrease in activity of the 5.9 form. By 3 h after metaphase the activity of the 6.4 form has dropped more sharply than the activity of the 6.7 form. By 6 h after metaphase only the activity of the 6.9 form is present in significant amounts in addition to the 7.1 form. The activity of these new acidic forms probably accounts for the reported increase in total thymidine kinase activity during mitosis and early S phase.     

Advancing the onset of mitosis by cell free preparations of Physarum polycephalum

Mitotic divisions in the plasmodia of Physarum polycephalum were advanced by about 1 h by applying to the plasmodial surface extracts of other plasmodia. Advancement of mitosis was greatest when the extracts were prepared from plasmodia harvested at late G2. The activity in the extracts responsible for the advancement of mitosis was found to be heat labile and non-dialysable. It is suggested that this activity belongs to proteins responsible for the regulation of mitosis.     

Characterization of the thymidine kinase of Physarum polycephalum

Thymidine kinase [ATP: thymidine 5'-phosphotransferase, EC 2.7.1.21] has been purified more than 3,500 fold from microplasmodia of Physarum polycephalum. Properties of the enzyme were determined on preparations purified 1,400 fold. Thymidine was transformed to dTMP while a stoichiometric quantity of ATP was transformed to ADP. 5-Iododeoxyuridine, 5-bromodeoxyuridine, and 5-fluorodeoxyuridine acted as competitive inhibitors for the thymidine substrate while 5-bromodeoxyuridine could be used as a substrate. In contrast uridine did not inhibit the enzymatic activity while deoxyuridine was a very poor competitive inhibitor in agreement with the observation that deoxyuridine could not be used as a substrate. Two apparent Michaelis constants were found for thymidine. Only the highest Michaelis constant could be decreased in the presence of increasing concentrations of ATP. Among the various nucleoside mono, di, or triphosphates studied only ATP and to a less extent dATP could be used as phosphate donors. A non competitive inhibition for thymidine was observed with dTTP. dTMP, dTDP, and dTTP acted as competitive inhibitors for ATP. None of the nucleoside mono, di, or triphosphates studied showed an activatory effect at low concentrations of ATP, even in the presence of dTTP. However, dUTP and dGDP acted as competitive inhibitors for ATP.     

Patterns of oscillation during mitosis in plasmodia ofPhysarum polycephalum

Summary The rhythmic contraction pattern in plasmodia ofPhysarum polycephalum was studied to determine whether characteristic changes occur during the synchronized nuclear division. An electrical method that measures the contraction rhythm in situ during several cell cycles was used. Biopsies of the plasmodia were taken at 17 min intervals for precise determination of the cell cycle stages and were correlated with the simultaneously measured contraction rhythm. All measurements were performed in a temperature controlled environment (27 °C) at 100% relative humidity with the plasmodia (less than 24 h old) growing on a semi-defined agar medium. A total of 14 different plasmodia have been examined, and on one occasion the plasmodium was followed through 3 subsequent mitoses. The mitotic stages were identified with aceto-orcein coloring techniques and by fluorescence methods. Except for a few cases where a mitotic asynchrony of 2–3 min was observed, the mitotic events occurred simultaneously in the nuclei within a single plasmodium. Both the occurrence of the first mitosis after inoculation and the intermitotic times were highly variable. Our study indicates that the contraction rhythm in plasmodia ofPhysarum is unperturbed during the synchronized nuclear division. However, in 5 of the 17 examined mitoses an amplitude decay was observed. We discuss possible explanations for the obtained results with emphasis on the applied techniques, interpretation of the oscillation patterns, and possible restrictions in the cell itself.     

Change of contractile behavior in plasmodia ofPhysarum polycephalum during mitosis

Summary Oscillations of ectoplasmic contraction in plasmodia of the myxomycetePhysarum polycephalum growing on agar containing semidefined medium were studied to determine if the contractile force is altered during the synchronous mitosis. In interphase the regular oscillations of contraction in the plasmodial sheet had an average period of 0.93 minutes in plasmodia growing at 24 °C. During mitosis the amplitude of these oscillations gradually decreased, ceasing for an average time of 2.7 minutes in 74% of the 23 plasmodia studied. Cessation of oscillating contractions in mitosis was accompanied by a decrease in the width of the channels embedded in the plasmodial sheet, and a decrease in the velocity of endoplasmic shuttle streaming usually to a complete standstill. Of 13 plasmodia in which the mitotic stage was very accurately determined, the stop in oscillating contractions occurred during metaphase in 10 plasmodia, and in prometaphase, anaphase, telophase in the 3 others. The cessation of contractile oscillations or of streaming did not occur absolutely simultaneously during mitosis in widely separated locations within one plasmodium, indicating mitotic asynchrony over a period of a few minutes within each plasmodium. We suggest that the halt of plasmodial migration during mitosis reported by others is caused by a decrease or cessation at slightly different times in the amplitude of ectoplasmic contractile oscillations in different areas of a plasmodium in mitosis resulting in an overall lack of coordination of endoplasmic flow throughout the plasmodium, thus temporarily halting migration. Possible physiological mechanisms linking a decrease in actomyosin contraction with the metaphase stage of mitosis are discussed.     

Phosphorylation of ribosomal proteins during the cell cycle of Physarum polycephalum

Physarum polycephalum has been used as a model system to study the phosphorylation of ribosomal proteins during the cell cycle. The results showed that the phosphate content of S3, the major ribosomal phosphoprotein in this organism, was constant during all phases of the cell cycle. No additional ribosomal phosphoproteins were observed. These results differ significantly from those reported earlier by Rupp, R.G., Humphrey, R.M. and Shaeffer, J.R. (Biochim. Biophys. Acta (1976) 418, 81-92) and suggest that the use of thymidine or hydroxyurea to synchronize cell population may affect the phosphorylation of ribosomal proteins. The results are discussed in relation to protein synthesis and cAMP level during the cell cycle.     

ADP-ribosyltransferase in isolated nuclei during the cell cycle of Physarum polycephalum.

ADP-ribosyltransferase was measured in isolated nuclei of Physarum polycephalum. Activity was determined with and without exogenous DNA and histones. During the synchronous cell cycle the activity measured with exogenous substrates exhibited a typical peak enzyme pattern with a maximum of activity in S-phase, whereas activity measured without exogenous substrates displayed a step enzyme pattern. Both activities doubled in each cell cycle.     

Synthesis of actinomycin-insensitive RNA during the first post-irradiation mitotic cycle,in the synchronously mitotic plasmodia of Physarum polycephalum

A sucrose density gradient analysis of³H-uridine pulse-labelled RNA from the first postirradiation mitotic cycle ofPhysarum polycephalum shows that all the density classes of RNA synthesized during this period are resistant to the peptide-antibiotic, actinomycin D. In fact, the synthesis is found to be greater in the presence of the drug. The heterogenously sedimenting synthetic activity here may represent a single species of RNA and its precursors or more than one kind of RNA. Further characterization of this RNA is meaningful in view of the actinomycin insensitivity of the postirradiation mitotic cycle itself to this antibiotic.     

Periodic events and cell cycle regulation in the plasmodia ofPhysarum polycephalum

The multinucleated plasmodia ofPhysarum polycephalum, a myxomycete, have been extensively used in cell cycle studies. The natural synchrony of mitosis and DNA synthesis, easy culture methods, the ready fusions obtainable between plasmodia, and the amenability to phase specific studies, employing physical and chemical perturbers, are some of the attractive features of this organism. Because of the absence of a Gl phase in the plasmodia, there is a crowding of cell cycle specific marker events at the G2/M boundary, which reflect features of both the G2/M and the Gl/S boundaries of a typical eukaryotic cell. Prominent among these are the synthesis and overall activity of thymidine kinase, the co-triggering of tubulin and histone genes, translation of their mRNA, the organization and duplication of the microtubular organizing centres of the mitotic spindle and the triggering of cdc 2 kinase activity. These above events have not only served as good markers to monitor the progress of the plasmodial cell cycle, but have also been fairly thoroughly analysed by means of specific perturbers such as DNA synthesis inhibitors, antimicrotubular drugs, UV-irradiation, heat-shock etc. Along with fusion studies, these perturbation studies have been helpful in the formulation of various models on regulation of mitosis. These above aspects as well as prospects for future studies employing this organism are discussed This paper is dedicated to the memory of the late Prof. S C K Nair, formerly University Professor of Physics.