Entamoeba histolytica: cell cycle and nuclear division

The cell cycle of Entamoeba histolytica, the duration of its phases, and the details of the nuclear division stages are described in this paper. Trophozoites from clone L-6, strain HM1:IMSS, were synchronized by colchicine. Synchrony was observed immediately after treatment and cultures remained synchronous for at least three replicative cycles with synchrony indexes between 13 and 15 hr. The stages of nuclear division were studied by light and electron microscopy. Four stages of the nuclear division were defined: prophase, early anaphase, late anaphase, and telophase. No metaphase stage was observed by light or electron microscopy. One of the first events in the nuclear division was the presence of a bud close to the juxtanuclear body, which grew to a daughter nucleus. The karyosome and the nuclear membrane remained throughout the mitotic process. Bundles of intranuclear microtubules were observed forming a "V" from the center of the nucleus to one of the poles, and associated with them, 12 to 16 chromosomes-like structures appeared. The results of these studies strongly suggest that division of E. histolytica involved a pleuromitotic process which is carried out in about 120 min.     

The relevance of the nuclear division cycle to radiosensitivity in yeast

Summary To investigate whether the nuclear division cycle could be related to cycle-specific changes in repair of ionizing radiation damage, we have determined the survival curves after -irradiation of samples taken frequently from synchronously dividing cultures of Saccharomyces cerevisiae cells. Survival was low in G1 and increased during S, reaching a maximum around the end of the S phase, which was maintained in G2. The shape of the survival curves for samples taken from later stages revealed a rapid cycle-specific drop in the radioresistance of individual cells. A simple model was formulated on the assumption that survival is greatly enhanced by the action of an enzymatic repair mechanism which requires duplicated but unsegregated DNA as a substrate. By taking into account the measurable age heterogeneity of samples taken from the synchronous cultures, this model was shown to fit the survival data closely. For an individual cell, the increasing survival during the S phase is thus attributable to a rising fraction of duplicated genome, whereas the rapid decrease in radioresistance at a later stage in the cell cycle may be interpreted as due to the final physical separation of sister chromatids. The start of the latter event was timed to the stage in mitosis when the nucleus begins to move towards the neck of the bud. The data are consistent with the hypothesis that the high radioresistance of cells in late S and G2 is due to the repair of double-stranded DNA breaks by a process involving recombination between sister chromatids.     

Kinetics of the nuclear division cycle of Aspergillus nidulans.

We have analyzed the cell cycle kinetics of Aspergillus nidulans by using the DNA synthesis inhibitor hydroxyurea (HU) and a temperature-sensitive cell cycle mutant nimT that blocks in G2. HU rapidly inhibits DNA synthesis (S), and as a consequence progression beyond S to mitosis (M) is blocked. Upon removal of HU the inhibition is rapidly reversible. Conidia (asexual spores) of nimT were germinated at restrictive temperature to synchronize germlings in G2 and then downshifted to permissive temperature in the presence of HU. This procedure synchronizes the germlings at the beginning of S in the second cell cycle after spore germination. We have measured the total duration of S, G2, and M as the time required for these cells to recover from the HU block and undergo the next nuclear division. The duration of S was defined by the time course of sensitivity to reintroduction of HU during recovery from the initial HU block. The cell cycle time was measured as the nuclear doubling time, and the duration of mitosis was determined from the mitotic index. The duration of G1 was calculated by subtracting the combined durations of S, G2, and M from the nuclear doubling time, and the length of G2 was calculated by subtracting S and M from the aggregate length of S, G2, and M. We have also determined the duration of the phases of the cell cycle during the first cycle after spore germination. In these experiments spores were germinated directly in HU without first being blocked in G2. Because the durations of G1, S, G2, and M for the first cell cycle after spore germination were identical with those previously determined for spores presynchronized at the beginning of S in the second cell cycle, we conclude that dormant conidia of A. nidulans are arrested at, or before, the start of S.     

Interdependence of cell cycle events inSchizosaccharomyces pombe. Terminal phenotypes of cell division cycle mutants arrested during dna synthesis and nuclear division

Summary Temperature-sensitive cell division cycle (cdc) mutants of the fission yeastSchizosaccharomyces pombe, previously characterized as defective in nuclear division were examined by thin section electron microscopy. All of the mutants failed to enter mitosis, rather they accumulated at one of four distinct terminal phenotypes. Class one were arrested with a nucleus rectangular in cross-section and a laterally situated spindle pole body (SPB). The second group had spherical or rectangular nuclei with a single SPB. The sole member of the third group wascdc 27. K 3, which had a spherical crenated nucleus with a single SPB from which microtubules emerged and extended into the cytoplasm. Allelic variants ofcdc 25 comprised the fourth group all of which displayed aberrant nuclear morphologies. Utilizing this ultrastructural data together with a knowledge of the transition points of these mutants a model for the interdependence of certain cell cycle event is proposed in which the initiation of DNA synthesis is uncoupled from the replication and separation of the SPB. This paper also provides new information on SPB structure inS. pombe. This is discussed in connection with the transient assembly of both spindle and cytoplasmic microtubules.     

Thymidylate synthetase during synchronous nuclear division cycle and differentiation of Physarum polycephalum

Thymidylate synthetase and thymidine kinase activities in wild type strain M₃b and in thymidine kinase-deficient mutant TU63 of Physarum polycephalum are studied. Whenever nuclear division occurs in macroplasmodia of wild type, thymidine kinase and thymidylate synthetase activities sharply increase, although the increase of thymidylate synthetase activity is less pronounced than thymidine kinase activity. This is also true for other investigated nuclear divisions during the life cycle of P. polycephalum. It is shown for the first time that thymidylate synthetase is a periodically fluctuating enzyme during the naturally synchronous nuclear division cycle of P. polycephalum with a peak of specific activity in the S phase. In macroplasmodia, as well as after germination of microsclerotia of M₃b, thymidine kinase is the dominant enzyme, whereas at the time of the precleavage mitosis in sporulating macroplasmodia thymidylate synthetase is the predominant enzyme. This study describes and compares both dTMP-synthesizing enzymes during proliferation and differentiation of the same organism.     

The Aspergillus nidulans bncA1 mutation causes defects in the cell division cycle, nuclear movement and developmental morphogenesis

Wild-type Aspergillus nidulans conidia are uninucleate. The mutation bncA1 (binucleated conidia) was first described as a single mutation located on chromosome IV that caused formation of approximately 25% binucleate and 1% trinucleate conidia. In this study, we show that bncA1 conidia exit G1 arrest earlier than the wild type. Germlings have hyphal elements with abnormal morphology, elevated numbers of randomly distributed nuclei and an irregular septation pattern. Older hyphal elements undergo mitotic catastrophe, suggesting the nuclear division cycle of internal (nonterminal) elements is not arrested. The bncA1 mutation also causes aberrant morphogenesis of the asexual reproductive structure, the conidiophore. Metulae and phialides are elongated and have incorrect numbers of nuclei. Phialides also have internal septation that appears to delineate hyphal-like elements. Heterokaryon analysis using strains with contrasting auxotrophic markers showed that the bncA1 mutation resulted in a higher frequency of diploid and multinucleated prototrophic conidia than control heterokaryons. These results suggest that in bncA1 strains multiple nuclei can move from the conidiophore vesicle to the metulae and/or from the phialide to the conidium. The bncA1 mutant also showed hypersensitivity to the anti-microtubule drugs thiabendazole and nocodazole, which is consistent with the defects in cell cycle regulation and nuclear movement. We propose that bncA has an important role in correctly regulating both the cell division cycle and nuclear movement.     

Cytological investigations of the parasexual cycle in fungi I. Nuclear fusion

Summary Investigations have been conducted to obtain specific, cytological evidence for nuclear fusions in heterokaryotic mycelium and in other vegetative (somatic) fungal cells. Results to-date have been inconclusive suggesting that such fusions possibly occur at a rate lower than 1 in 10⁷. It is also proposed that, in addition to the rare occurrence of somatic nuclear fusions, other processes may initiate the parasexual or some similar cycle. These processes are based upon the possible transfer of genetic material during pairing of unlike, vegetative nuclei or during close associations noted between mitochondria and nuclei.     

The continuum model and c-myc synthesis during the division cycle

Discordant results on the synthesis of c-myc gene products during the division cycle are reanalyzed and shown to be understood in light of the continuum model. It is proposed that there is no G1-phase dependence of c-myc synthesis. The large amount of data supporting G1-specific syntheses and a G(0) state must be re-examined.