ABSTRACT
The multinucleated plasmodia of Physarum 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.
ABSTRACT
A sucrose density gradient analysis of 3H-uridine pulse-labelled RNA from the first postirradiation mitotic cycle of Physarum 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.
ABSTRACT
Synchronously mitotic surface Plasmodia of Physarum polycephalum were ultraviolet- irradiated at different times during G2-phase (– 4 h to – 20 min with respect to metaphase), and treated immediately thereafter with varying concentrations of caffeine. It was observed that ultraviolet-induced mitotic delay is reduced significantly by this methylxanthine. In plasmodia irradiated between – 4 and – 1 h with respect to metaphase, the effect was concentration-dependent and the need for a certain threshold dose for obtaining the reduction in delay was apparent. However, higher doses than this were fairly toxic when applied at this part of the cycle and led to more mitotic delay than that obtained with UV alone. The most striking observation made during this study was the phase-specific precipitous effect seen in those plasmodia irradiated at about 20 min before mitosis which almost eliminated the long delay due to ultraviolet-irradiation. These results are discussed in the context of some of the known effects of ultraviolet and caffeine on a mitosis-promoting factor. It is proposed that the significant reduction of ultravioletinduced mitotic delay reported here is due to the reactivation of the ultraviolet-inactivated mitosis-promoting factor by caffeine. Alternatively, it is possible that caffeine may prevent the inactivation of this factor by ultraviolet.