EFFECT OF CENTRIFUGATION ON THE DEVELOPMENT AND TIMING OF PREMITOTIC POSITIONING OF THE NUCLEUS IN ADIANTUM PROTONEMATA

When single-celled protonemata of Adiantum capillus-veneris L. were centrifuged immediately before transferring to darkness from continuous irradiation with red light, their nuclei were displaced basipetally. Both filamentous and branched protonemata were obtained. The stronger the centrifugal acceleration, the more frequently the branched protonemata were induced.
The effect of centrifugation at 1,300 x g for 15 min on nuclear displacement was different at different stages of the cell cycle. In early G₁ phase, the nucleus was easily displaced by centrifugation, but quickly returned to the original position after centrifugation. In late G₁ phase, the nucleus was displaced, but after centrifugation it never came back to the original position. In late G₂ and M phases, the nucleus was no longer displaced by the centrifugation. Premitotic positioning of the nucleus in cytokinesis took place about 5 hr before cell plate formation in all centrifugal treatments described above.     

Protein Synthesis during Photocontrolled Progression of the Cell Cycle in Single-celled Protonemata of the Fern Adiantum Capillus-veneris

Protein synthesis during photoinduced, synchronous progression of the cell cycle in single-celled protonemata of the fern Adiantum capillus-veneris was studied by tracer techniques. Nuclei of the protonemata were labelled with ³H-thymidine during spore germination so that the amount of ³H incorporated into the TCA-insoluble fraction of the cells could be used as a measure of the cell number in each sample. The rate of the incorporation of ¹⁴C-amino acids into TCA-insoluble materials was not significantly varied at different stages of the cell cycle or by treatment with blue light. Extracts of cells labelled with ³⁵S-methionine at various times after the transfer from red light condition (G₀) to darkness (G₁ to S) were analyzed by two-dimensional gel electrophoresis. At least 3 of about 200 spots showed significant changes in intensity on fluorograms. Spot A (molecular weight 20,000, isoelectric point 6.3) was detectable only in early G₁, whereas spot B (molecular weight 19,500, isoelectric point 6.3) was found only in the late G₁ and S phases. When the cells were exposed to blue light before the dark incubation, the times of disappearance of spot A and appearance of spot B were advanced depending upon the progression of the cell cycle but not upon the clock time.     

cAMP IN THE CELL CYCLE OF THE DINOFLAGELLATE CRYPTHECODINIUM COHNII (DINOPHYTA)

The second messenger cAMP is a key regulator of growth in many cells. Previous studies showed that cAMP could reverse the growth inhibition of indoleamines in the dinoflagellate Crypthecodinium cohnii Biecheler. In the present study, we measured the level of intracellular cAMP during the cell cycle of C. cohnii . cAMP peaked during the G₁ phase and decreased to a minimum during S phase. Similarly, cAMP-dependent protein kinase activities peaked at both G₁ and G₂+M phases of the cell cycle, decreasing to a minimum at S phase. Addition of N6, O₂'-dibutyryl (Bt₂)-cAMP directly stimulated the growth of C. cohnii . Flow cytometric analysis of synchronized C. cohnii cells suggested that 1 mM cAMP shortened the cell cycle, probably at the exit from mitosis. The size of Bt₂-cAMP treated cells at G₁ was also larger than the control cells. The present study demonstrated a regulatory role of cAMP in the cell cycle progression in dinoflagellates.     

Synthesis of protein and mRNA is necessary for transition of suspension-cultured Catharanthus roseus cells from the G1 to the S phase of the cell cycle

The effects of inhibition of the synthesis of protein, mRNA or rRNA on the progression of the cell cycle have been analyzed in cultures of Catharanthus roseus in which cells were induced to divide in synchrony by the double phosphate starvation method. The partial inhibition of protein synthesis at the G₁ phase by anisoniycio or cycloheximide caused the arrest of cells in the G₁ phase or delayed the entry of cells into the S phase. When protein synthesis was partially inhibited at the S phase, cell division occurred to about the same extent as in the control. When asynchronously dividing cells were treated with cycloheximide, cells accumulated in the G₁ phase, as shown by flow-cytometric analysis. The partial inhibition of mRNA synthesis by α-amanitin at the G₁ phase caused the arrest of cells in the G₁ phase, although partial inhibition of mRNA synthesis at the S phase had little effect on cell division. In the case of inhibition of synthesis of rRNA by actinomycin D at the G₁ phase, initiation of DNA synthesis was observed, but no subsequent DNA synthesis or the division of cells occurred. However, the addition of actinomycin D during the S phase had no effect on cell division. These results suggest that specific protein(s), required for the progression of the cell cycle, are synthesized in the G₁ phase, and that the mRNA(s) that encode these proteins are also synthesized at the G₁ phase.     

CELL CYCLE PROPERTIES OF DIFFERENTIATING SPERMATOGONIA IN ADULT SPRAGUE-DAWLEY RATS

The duration of the mitotic cycle and of its components was analysed for each of the six successive generations of differentiating spermatogonia (A₁, A₂, A₃, A4, intermediate and B), using radioautographed whole mounts of seminiferous tubules from testes of adult Sprague-Dawley rats. Cell cycles were determined from two successive waves of per cent labeled metaphases obtained during the period of 81 hr after a single dose of ³H-thymidine. Except for the A₁ spermatogonia, all spermatogonial types (A₂ to B) had similar cell cycle durations of 41-42.5 hr and comparable pre-DNA synthesis phases (G₁) of 11-13 hr. Although the combined duration of DNA synthesis (S) and the post-synthesis phase (G₂) remained identical for all the cell types including A₁, there was a progressive lengthening of the S period at the expense of G₂ during the process of spermatogonial maturation. This change was most marked during the transition from A₁ to A₃ spermatogonia when the S period increased from 14 hr to 21 hr, and the G₂ phase shortened from 13 hr to 7.5 hr. This feature seems to be unique to germ cells and may be associated with an increasing amount of heterochromatin in the nucleus. Excluding the development of type A₁ cells, the entire process of spermatogonial maturation lasted for 208 hr. Combined data on cell cycle times indicated that every 313 hr or 13 days, a new sequence of spermatogonial differentiation was initiated by the A₁ cells. This was equivalent to the duration of one 'cycle' of the seminiferous epithelium as measured by other techniques.     

Monocytic differentiation of HL60 cells induced by potent analogs of vitamin D3 precedes the G1/G0 phase cell cycle block

Abstract. Differentiation of mammalian cells is accompanied by reduced rates of proliferation and an exit from the cell cycle. Human leukemic cells HL60 present a widely used model of neoplastic cell differentiation, and acquire the monocytic phenotype when exposed to analogs of vitamin D₃ (VD₃). The maturation process is accompanied by two blocks in the cell cycle: an arrest in the G₁/G₀ phase, and a recently described G₂+ M block. In this study we have analyzed the traverse of the cell cycle phases of the well-differentiating HL60-G cells exposed to one of ten analogs of VD₃, and compared the cell cycle effects of each compound with its potency as a differentiation-inducing agent. We found that in general there was a good correlation between the effects of these compounds on the cell cycle and on differentiation, but the best cell cycle predictor of differentiation potency was the extent of accumulation of the cells in the G₂ compartment. All analogs induced a marked decrease in the mitotic index, and polynucleation of HL60 cells was produced, especially by compounds which were effective as inducers of differentiation. Time course studies showed that induction of differentiation was accompanied by a transient increase of the proportion of cells in the G₂+ M compartment, but preceded the G₁ to S, and the G₂ compartment blocks. These studies indicate that complex changes in the cell cycle traverse accompany, but do not precede, the acquisition of the monocytic phenotype by HL60 cells.     

A Changing Pattern of the Cell Cycle during the First Two Cleavage Divisions of the Mouse

The cell cycles of the early cleavage stages of the mouse were analyzed by examining Feulgen-stained ova. The period from ovulation to the completion of second cleavage division was investigated. The ova donors were C57BL/6 × DBA/2 female mice, which were hormonally superovulated. To estimate the durations of DNA synthesis and mitotic phases of the cleavage divisions, the ova were pooled into culture medium, and as a function of time, aliquots were removed from the batch of pooled ova. The ova specimens were Feulgen-stained and classified as the ova nuclei in G₁, S, G₂ or mitosis by use of a cytophotometric technique and then the durations of these phases were determined by probit analysis.
The pronuclear stage had a generation time of 11 hr, with a G₁ phase of 6 hr and a short S phase of 1.7 hr. In contrast the two-cell stage had a generation time of 18 hr, with a G₁ phase of 2 hr and an S phase of 3 hr. The duration of cleavage division also changed; the first cleavage division spanned 3 hr while the second spanned 1 hr.     

Cell cycle progression in human cells following re-oxygenation after extreme hypoxia: consequences concerning initiation of DNA synthesis

Abstract. The initiation of DNA synthesis and further cell cycle progression in cells during and following exposure to extremely hypoxic conditions in either G₁ or G₂+M has been studied in human NHIK 3025 cells. Populations of cells, synchronized by mitotic selection, were rendered extremely hypoxic (< 4 p.p.m. O₂) for up to 24n h. Cell cycle progression was studied from flow cytometric DNA recordings. No accumulation of DNA was found to take place during extreme hypoxia. Cells initially in G₁ at the onset of treatment did not enter S during up to 24 h exposure to extreme hypoxia, but started DNA synthesis in a highly synchronous manner within 1.5 to 2.25 h after reoxygenation. The duration of S phase was only slightly affected (increased by ≅10%) by the hypoxic treatment. This suggests that the DNA synthesizing machinery either remains intact during hypoxia or is rapidly restored after reoxygenation. Cells initially in G₂ at the onset of hypoxia were able to complete mitosis, but further cell cycle progression was blocked in the subsequent G^ Following reoxygenation, these cells progressed into S phase, but the initiation of DNA synthesis was delayed for a period corresponding to at least the duration of normal G₁ and did not appear in a synchronous manner. In fact, cell cycle variability was found to be increased rather than decreased as a result of exposure to hypoxia starting in G₂. We interpret these findings as an indication that important steps in the preparation for initiation of DNA synthesis take place before mitosis. Furthermore, the change in cell cycle duration induced by hypoxia commencing in G₁ is of a nature other than that induced by hypoxia commencing in other parts of the cell cycle.     

Influence of denervation on the regeneration of Pleurodele limbs

Abstract. A cytophotometric study of Feulgen-stained mesenchymal cell nuclei from regeneration blastemas of both innervated and denervated limbs over the 1st 7 days following the midbud stage showed a diminution of the percentage of cells in the S + G₂ phases and a corresponding augmentation of the percentage of cells in the G₀+ G₁ phases. This change, which was temporally correlated with the redifferentiation of the innervated blastemas, was greater in denervated blastemas, even though they do not redifferentiate. From these results, it is concluded that the denervation of midbud blastemas brings about either an extension of the G₁ phase or an exiting from the cell cycle to G₁ (G_0–1), or both phenomena.     

Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Abstract. Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G¹, S and G₂+ M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about twofold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle ( T _c) was 15-3 h for PB-3 cells and 12-4 h for PB-1 cells. Shortening in T _c for the transformed cells was due to a decrease of nearly 30% in mean duration of the G ₁ phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G₂+ M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G¹ phase of the cell cycle.     

Normal G1/S transition and prolonged S phase within one cell cycle after seeding cells in the presence of an ornithine decarboxylase inhibitor

Abstract. We have previously found that DNA replication was affected within one cell cycle after seeding Chinese hamster ovary (CHO) cells in the presence of the polyamine biosynthesis inhibitor 2-difluoromethylornithine (DFMO). We could, however, not rule out if this was due to an effect on the G₁/S transition and/or on DNA synthesis elongation. In the present paper, we use a bromodeoxyuridine-flow cytometric method to more specifically study the G₁/S transition, the S phase length, and the progression of cells from S phase through G₂+ M and into G₁, after seeding plateau phase CHO cells at low density in the absence or presence of 5 mM DFMO. We report here that DFMO-induced polyamine depletion increased the length of the S phase within one cell cycle after seeding of CHO cells in the presence of the inhibitor. No effect on the G₁/S transition was observed until 2 days after seeding, suggesting that a DFMO-induced lengthening of the G₁ phase occurred later than the effect on S phase progression. These results imply that the G₂+ M phase was not prolonged until 2 days after seeding CHO cells in the presence of DFMO.     

Age-related changes in the cell kinetics of rat foot epidermis

Abstract. The durations of the cell cycle and its component phases have been determined for the basal layer of the epidermis of the skin from the upper surface of the hind foot of the rat using single pulse [³H]-thymidine labelling and the percent labelled mitosis (PLM) technique. Rats of three age groups were used, namely 7, 14 and 52 weeks. The duration of DNA synthesis (T_s) and the G₂ plus M phase (Tg₂± m) were comparable in 7-week and 52-week-old rats ( P > 0–1). The major difference between 7-week and 52-week-old rats was in the duration of the G₁ phase (Tg₁). In 7-week-old rats Tg₁ was 15.0 ± 0.8 h and in 52-week-old rats Tg₁ was 31.2 ± 3.5 h. A consequence of this variation was that the overall duration of the cell cycle was longer in 52-week-old rats (53.9 ± 5.3 h) than in 7-week-old rats (30.1 ± 1.3 h).
Difficulties were found in fitting a simple curve to the PLM data for 14-week-old rats. This suggests that the proliferative cell population of the epidermis of rats of this age group may be heterogeneous. A satisfactory fit to the data was obtained using a computer model which assumed that the proliferative population of the epidermis of 14-week-old rats was a mixture of cells with cell cycle parameters the same as those of the 7-week and the 52-week-old rats. These two sub-populations of relatively slowly and rapidly proliferating cells were present in the ratio of 2:1.     

EFFECTS OF ACTINOMYCIN D AND PUROMYCIN ON THE CELL PROGRESS FROM M TO G1 AND S STAGES IN CULTURED MOUSE LEUKEMIA L5178Y CELLS

Actinomycin D (0.5 μg/ml) did not prevent M stage cells from entering G₁ stage, but blocked their progress from G₁ to S stage. The position of the block was approximately 1.4 hr before S stage or just after the beginning of G₁ stage. Actinomycin D in this concentration also significantly depressed uridine-³H uptake into G₁ stage cells, but did not suppress leucine-³H uptake by M and G₁ cells. This suggests that some proteins may be synthesized in M and G₁ stage cells by messenger RNA left over from the previous cell cycle. However, entry of G₁ cells into S stage would require synthesis of new messenger RNA near the beginning of G₁ stage. Puromycin (10 μg/ml) did not prevent M cells from entering G₁ stage, but blocked their progress from G₁ to S stage. The site of blockage was about 0.7 hr before S stage or in the first two-third of G₁ stage. This might be the site where the cells synthesize new G₁ proteins necessary for entry to S stage.
Comparison of sensitivities of G₁ and G₂ stages to the two antibiotics reveals that the puromycin sensitivity of G₁ cells was similar to that of G₂ cells, but the actinomycin D sensitivity of G₁ was greater than that of G₂ cells.     

ON THE RESTING STAGES OF THE JB-1 ASCITES TUMOUR

Cytophotometric determination of single-cell DNA after repeated ³H-thymidine labelling of the JB-1 ascites tumour in the plateau phase of growth showed a massive accumulation of unlabelled cells with both G₁ and G₂ content. Autoradiography combined with cytophotometry or colcemid block demonstrated that some of these unlabelled cells were rapidly triggered into the cell cycle when plateau tumours were transferred to new hosts. This indicated that tumour cells may be held up in non-cycling stages corresponding to both the G₁ and the G₂ phase of the cell cycle.     

Laser scanning cytometer (LSC) analysis of fraction of labelled mitoses (FLM)

Abstract. In this report we describe the successful application of a novel microscope-based multiparameter laser scanning cytometer (LSC) to measure duration of different phases of cell cycle in HL-60 human leukaemic cell lines by the fraction of labelled mitoses (FLM) method. Exponentially growing cells were harvested after various time intervals following pulse-labelling with 5'-bromo-2'-deoxyuridine (BrdUrd), cytocentrifuged, fixed in ethanol, and then exposed to UV light to induce DNA strand breaks at the sites of incorporated BrdUrd. The 3'OH termini of the photolytically generated DNA strand breaks were labelled with BrdUTP in the reaction catalysed by exogenous terminal deoxynucleotidyl transferase (TdT), followed by FITC-labelled BrdUrd antibodies. DNA was counterstained with propidium iodide (PI). Due to differences in chromatin structure between the interphase and mitotic cells, the LSC identified the latter by virtue of their higher red (PI) fluorescence intensity values among all pixels over the measured cell. To confirm that the cells selected were indeed cells in mitosis, predominantly in metaphase, the recorded X-Y coordinates of selected cells were used to re-position the cell for their visual examination. From the time lapse analysis of percentage BrdUrd-labelled cells progressing through mitosis it was possible to calculate the duration of individual phases of the cell cycle. The duration of S (T_s) and G₂+ M (T_G2+M) was 8 and 3 h, respectively, and the minimal duration of G₂ (T_G2) was 2 h. The cell cycle time (T_c) estimated for the cohort of the most rapidly progressing cells was 13 h. The ability to automatically and rapidly discriminate mitotic cells combined with the possibility of their subsequent identification by image analysis makes LSC the instrument of choice for the FLM analysis.     

Effect of separase depletion on ionizing radiation-induced cell cycle checkpoints and survival in human lung cancer cell lines

Abstract.   Objectives : This study is to evaluate the effect of separase depletion on cell cycle progression of irradiated and non-irradiated cells through the G₂/M phases and consecutive cell survival. Materials and methods : Separase was depleted with siRNA in two human non-small cell lung carcinoma (NSCLC) cell lines. Cell cycle progression, mitotic fraction, DNA repair, apoptotic and clonogenic cell death were determined. Results : By depletion of endogenous separase with siRNA in NSCLCs, we showed that separase affects progression through the G₂ phase. In non-irradiated exponentially growing cells, separase depletion led to an increased G₂ accumulation from 17.2% to 29.1% in H460 and from 15.7% to 30.9% in A549 cells and a decrease in mitotic cells. Depletion of separase significantly ( P <  0.01) increased the fraction of radiation-induced G₂ arrested cells 30–56 h after irradiation and led to decrease in the mitotic fraction. This was associated with increased double-strand break repair as measured by γ-H2AX foci kinetics in H460 cells and to a lesser extent in A549 cells. In addition, a decrease in the expression of mitotic linked cell death after irradiation was found. Conclusions : These results indicate that separase has additional targets involved in regulation of G₂ to M progression after DNA damage. Prolonged G₂ phase arrest in the absence of separase has consequences on repair of damaged DNA and cell death.     

The effects of interleukin 4 on the cell cycle of a human B-cell lymphoma line

Abstract. Exposure of Farage, a human B-cell lymphoma line, to IL-4 for 3–11 days led to inhibition of tritiated thymidine ([³H]dT) uptake by the cells. Study of the incorporation of 5-bromodeoxyuridine by Farage cells showed that IL-4 reduced significantly the number of cells in the S phase of the cell cycle and increased the proportion of cells in the G₁ phase. Limiting dilution analysis of proliferation demonstrated that IL-4 decreased the frequency of clone-forming cells by 40%. IL-4 did not reduce the viability of Farage cells. On the contrary, IL-4 diminished the spontaneous death of Farage cells in culture, as determined by pulse chase analysis of cells which were labelled with [³H]dT. Moreover, the pre-treatment of Farage cells with IL-4 prevented their death induced by exposure to a high dose of staurosporine. IL-4 abrogated the staurosporine-induced arrest of cells in the G₂+ M phase and replaced it by accumulation of cells in the G₁ phase. IL-4 protected Farage cells from the radioactive suicide caused by the uptake of [³H]dT by dividing cells. The cytokine failed to prevent the damage to Farage cells exerted by mitomycin C, which affected cellular DNA regardless of the phase of the cell cycle. The data obtained showed that IL-4 inhibited the division of B cells by arresting their progression through the early stages of the cell cycle. This inhibition of the cell efflux from G₁ phase plays an important role in the protection against cell death during further stages of the cell cycle.     

Flow cytometric analysis of the recruitment of G0 cells in human epidermis in vivo following tape stripping

Abstract. Tape stripping of human skin elicits a proliferative response of a synchronously-dividing group of cells. The progress of this cohort of cells has been monitored using two windows in the cell cycle, one located in mid-S phase and the other centred around G₂+ M. The cellular DNA is measured with flow cytometry, the windows are defined by two ranges in the DNA histogram.
The cohort can be described as the recruitment of cells from a pre-existing G₀ compartment which consists of 76% of all proliferative cells. The duration of the S phase is calculated to be 10.2 hr and G₂+ M phase 5.1 hr. The cell cycle time of 39 hr for normal human keratinocytes derived from these figures is in line with recent values obtained by different techniques.     

Effect of the auxin, 2-(2-methyl-4-chloro-phenoxy)propionic acid, on cell cycle regulation in maize embryonic tissues

During seed maturation, cells from embryonic tissues stop division at different phases of the cell cycle. In maize, neither these phases nor the effect of exogenous auxin on them are known. Disinfected whole maize ( Zea mays L. Mexican commercial hybrid H30) seeds or sectioned embryonic axes were incubated in Murashige and Skoog medium, with or without 2-(2-methyl-4-chlorophenoxy)propionic acid (MCPP), a synthetic auxin. For some in vitro experiments, radioactive [³H]-thymidine was also added. After the stated incubation period, meristems of mesocotyl, primary and seminal roots from embryonic axes were dissected, fixed, and analyzed under a microscope. The percentage of mitotic indices was recorded. In the labeling experiments, labeled and non-labeled percentage of mitotic figures (MI %) were determined. It was found that cell division is a programmed event in the meristematic tissues of maize embryonic axes. Populations of cells entering cell division were obseved during the germination process. The mesocotyl was the first tissue to divide, followed by seminal and primary roots.
Meristematic cells from dry embryos are arrested during the G₂ and G₁ phases of the cell cycle. MCPP has a differential effect, stimulating G₂ cells to enter cell division. It is concluded that MCPP might regulate the cell cycle at specific points.