Variations in Several Responses of HeLa Cells to X-Irradiation during the Division Cycle

Several responses of synchronized populations of HeLa S3 cells were measured after irradiation with 220 kev x-rays at selected times during the division cycle. (1) Survival (colony-forming ability) is maximal when cells are irradiated in the early post-mitotic (G₁) and the pre-mitotic (G₂) phases of the cycle, and minimal in the mitotic (M) and late G₁ or early DNA synthetic (S) phases. (2) Markedly different growth patterns result from irradiation in different phases: (a) Prolongation of interphase (division delay) is minimal when cells are irradiated early in G₁ and rises progressively through the remainder of the cycle. (b) Cells irradiated while in mitosis are not delayed in that division, but the succeeding division is delayed. (c) Persistence of cells as metabolizing entities does not depend on the phase of the division cycle in which they are irradiated. (3) Characteristic perturbations of the normal DNA synthetic cycle occur: (a) Cells irradiated in M suffer a small delay in the onset of S, a slight prolongation of S, and a slight depression in the rate of DNA synthesis; the major delay occurs in G₂. (b) Cells irradiated in G₁ show no delay in the onset of S, and essentially no alteration in the duration or rate of DNA synthesis; G₂ delay is minimal. (c) Cells irradiated in S suffer an appreciable S prolongation and a decreased rate of DNA synthesis; G₂ delay is shorter than S delay.     

Ultraviolet Light-Induced Division Delay in Synchronized Chinese Hamster Cells

The age-dependent, ultraviolet light (UVL) (254 nm)-induced division delay of surviving and nonsurviving Chinese hamster cells was studied. The response was examined after UVL exposures adjusted to yield approximately the same survival levels at different stages of the cell cycle, 60% or 30% survival. Cells irradiated in the middle of S suffered the longest division delay, and cells exposed in mitosis or in G₁ had about the same smaller delay in division. Cells irradiated in G₂, however, were not delayed at either survival level. It was further established, after exposures that yielded about 30% survivors at various stages of the cycle, that surviving cells had shorter delays than nonsurvivors. This difference was not observed for cells in G₂ at the time of exposure; i.e., neither surviving nor nonsurviving G₂ cells were delayed in division. The examination of mitotic index vs. time revealed that most cells reach mitosis, but all of the increase in the number of cells in the population can be accounted for by the increase of the viable cell fraction. These observations suggest strongly that nonsurviving cells, although present during most of the experiment, are stopped at mitosis and do not divide. Cells in mitosis at the time of irradiation complete their division, and in the same length of time as unirradiated controls. Division and mitotic delays after UVL are relatively much larger than after X-ray doses that reduce survival to about the same level.     

Timing and Regulation of Nuclear and Cortical Events in the Cell Cycle of Tetrahymena pyriformis*

SYNOPSIS. Using continuous flow cultures based on the chemostat principle, we varied the cell generation times of the ciliate Tetrahymena pyriformis strain GL, from 4.9 to 22.2 hr and studied various parameters of the cell cycle at 28 C. These included: the duration of the periods required for oral morphogenesis, macronuclear division, cell division, G₁ S, and G₂. The size of individual cells was also measured. Independent of the growth rate, the period of oral morphogenesis occurred during the last 90 min of the cell cycle. In all cases macronuclear and cell divisions took place during the last part of these 90 min, and the final macronuclear separation occurred just before final cell separation. The S-period increased slightly, while the G₁ and G₂ both increased in roughly the same relative proportion to the increasing generation times. Slowly growing cells (generation time 20.5 hr) were shorter but broader and somewhat larger in volume than quickly growing cells (generation time 4.9 hr).     

The cell cycle of<Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis>: the role of the commitment point

Chlamydomonas reinhardtii cells can double their size several times during the light period before they enter the division phase. To explain the role of the commitment point (defined as the moment in the cell cycle after which cells can complete the cell cycle independently of light) and the moment of initiation of cell division we investigated whether the timing of commitment to cell division and cell division itself are dependent upon cell size or if they are under control of a timer mechanism that measures a period of constant duration. The time point at which cells attain commitment to cell division was dependent on the growth rate and coincided with the moment at which cells have approximately doubled in size. The timing of cell division was temperature-dependent and took place after a period of constant duration from the onset of the light period, irrespective of the light intensity and timing of the commitment point. We concluded that at the commitment point all the prerequisites are checked, which is required for progression through the cell cycle; the commitment point is not the moment at which cell division is initiated but it functions as a checkpoint, which ensures that cells have passed the minimum cell size required for the cell division.     

Comparative effects of 60Co gamma-rays and neon and helium ions on cycle duration and division probability of EMT 6 cells. A time-lapse cinematography study

Exponentially growing cultures of EMT 6 cells were irradiated in vitro with neon ions, helium ions or 60Co gamma-rays. Time-lapse cinematography allowed the determination, for individual cells, of cycle duration, success of the mitotic division and the age of the cell at the moment of irradiation. Irradiation induced a significant mitotic delay increasing proportionally with the delivered dose. Using mitotic delay as an endpoint, the r.b.e. for neon ions with respect to 60Co gamma-rays was 3.3 +/- 0.2 while for helium ions it was 1.2 +/- 0.1. Mitotic delay was greatest in those cells that had progressed furthest in their cycle at the time of irradiation. No significant mitotic delay was observed in the post-irradiation generation. Division probability was significantly reduced by irradiation both in the irradiated and in the post-irradiated generation. The reduction in division probability obtained with 3 Gy of neon ions was similar to that obtained after irradiation with 6 Gy of helium ions or 60Co gamma-rays.     

Blue Light Inhibits Mitosis in Tissue Culture Cells

Irradiation of the mitotic (prophase and prometaphase) tissue culture PK (pig kidney embryo) cells using mercury arc lamp and band-pass filters postponed or inhibited anaphase onset. The biological responses observed after irradiation were: (i) normal cell division, (ii) delay in metaphase and then normal anaphase and incomplete cytokinesis, (iii) exit into interphase without separation of chromosomes, (iv) complete mitotic blockage. Cell sensitivity to the light at wavelengths from 423 and 488 nm was nearly the same; to the near UV light (wavelength 360 nm) it was 5–10 times more; to the green light (wavelength >500 nm) it was at least 10 times less. To elucidate the possible mechanism of the action of blue light we measured cell adsorption and examined cell autofluorescence. Autofluorescence of cytoplasmic granules was exited at wavelengths of 450–490 nm, but not at >500 nm. In mitotic cells fluorescent granules accumulated around the spindle. We suppose blue light irradiation induces formation of the free radicals and/or peroxide, and thus perturb the checkpoint system responsible for anaphase onset.     

Growth kinetics of cells following freezing in liquid nitrogen

The growth kinetics of cells frozen to ?196 °C were monitored after thawing by various techniques. Progression through the cell cycle in the exposed generation was observed by monitoring cell growth either via multiplicity counts or by electronic cell counts of trypsinized suspensions. Subsequent generations were followed by time-lapse microcinematography.The division delay in the exposed generation of exponential-phase cells was dependent on cell age at the time of freezing and varied from 4 to 8 hr. The time of the first generation was still prolonged significantly but subsequent generations revealed cell cycle times that are comparable to unfrozen cells. In the case of plateau-phase cells, mitosis was delayed 7 hr in the exposed generation. This is 50% longer than the delay seen for pre-DNA synthetic g₁ cells in exponentially growing cultures.A rather important observation in this study was that frozen-thawed cells which divide once will probably continue dividing whereas eventual nonsurvivors are not likely to divide at all. The latter, however, remain active for more than 35 hr as observed microscopically, hence possibly indicating residual metabolic activity.     

A relationship between nuclear DNA and RNA synthetic activities and the changes produced by n-methyl-n-nitroso urethane: A study using Amoeba proteus as a single cell model

Changes caused by a carcinogen generally vary from one cell to another even among similar types of cells. The following work investigates the degree to which damage (inhibition of division, lethality, or inherited cellular changes) caused by N-methyl-N-nitroso urethane (MNU) alters at different times during the cell cycle, and relates fluctuations in the sensitivity of cells to changes in their DNA and RNA synthetic activities—possibly in the configuration of their DNA—at the time of treatment.Studies on amoebae exposed to MNU for short periods at 50 different times in their cell cycle led to the following conclusions: amoebae are sensitive to MNU at all ages, but the dose needed to produce lethal damage to young and old cells varies by a factor of 3. Cells are most sensitive at the time of division and during the peak of DNA synthesis. Smaller changes are found during the G₂ phase, some of which occur at times of intensive RNA synthesis. Transfer of nuclei between treated and control cells proved that the changing sensitivity of the cells, as shown by both inherited changes and lethal damage, was dependent on changes in their nuclei. Though the cytoplasm could be affected directly by MNU, i.e. in the absence of a nucleus, supralethal doses 2–6 times whole cell dose were required to either kill the cell or to cause a recognizable change in the offspring of viable cells. Experiments with cells having altered nuclear/cytoplasmic ratios showed that the relative insensitivity of older cells was not due to the increased volume of their cytoplasm. However, a possible involvement of cytoplasm in the repair of nuclear damage is suggested by the ability of control cytoplasm to alleviate some nuclear damage, particularly in S phase cells.     

Conjugation in Tetrahymena: the relationship between the division cycle and cell pairing

Conjugation, a sexual stage in the life cycle of Tetrahymena, is marked by the pairing of two cells of opposite mating types. Pairing establishes cytoplasmic continuity between the two cells and initiates the complex of nuclear events involved in sexual exchange. After mixing cells of opposite mating types in nonnutrient medium, a 3-hr refractory period ensues before pairing begins.A wave of cell division occurs concurrently with the onset of pairing. However, although all cells pair, the population does not double. This indicates that some cells do not divide and yet are capable of pairing. Apparently division per se is not required for pairing but does occur in most of the cells.Autoradiographic analysis demonstrates that the cells that divide before pairing were at a stage in the cell cycle beyond the initiation of macronuclear replication at the time they were transferred to nonnutrient medium. Cells that did not divide were in G₁ at the time of shift-down. Thus, neither replication nor division is required to be able to fuse. However, since fusion occurs only in G₁ and most cells are not in G₁ at the time of shift-down, a traverse of the cell cycle is required.Shift-down induces G₁ arrest and preparations for the mating reaction. Mixing the cells induces a synchronous wave of division for cells beyond the $\text{G}{}_1\text{S}$ interface. Preparations for the mating reaction occur independently of but simultaneous with the preparations for cell division.     

Influence of stem-cell cycle time on accelerated re-population during radiotherapy in head and neck cancer

Objectives

Tumour re‐population during radiotherapy was identified as an important reason for treatment failure in head and neck cancers. The process of re‐population is suggested to be caused by various mechanisms, one of the most plausible one being accelerated division of stem‐cells (i.e. drastic shortening of cell cycle duration). However, the literature lacks quantitative data regarding the length of tumour stem‐cell cycle time during irradiation.

Materials and methods

The presented work suggests that if accelerated stem‐cell division is indeed a key mechanism behind tumour re‐population, the stem‐cell cycle time can drop below 10 h during radiotherapy. To illustrate the possible implications, the mechanism of accelerated division was implemented into a Monte Carlo model of tumour growth and response to radiotherapy. Tumour response to radiotherapy was simulated with different stem‐cell cycle times (between 2 and 10 h) after the initiation of radiotherapy.

Results

It was found that very short stem‐cell cycle times lead to tumour re‐population during treatment, which cannot be overcome by radiation‐induced cell kill. Increasing the number of radiation dose fractions per week might be effective, but only for longer cell cycle times.

Conclusion

It is of crucial importance to quantitatively assess the mechanisms responsible for tumour re‐population, given that conventional treatment regimens are not efficient in delivering lethal doses to advanced head and neck tumours.     

Age-related alterations in cell division and cell cycle kinetics in control and trimethyltin-treated lymphocytes of human individuals

Trimethyltin chloride induced age-related suppression of cell division and cell cycle kinetics in human peripheral blood lymphocytes cultured in RPMI 1640 culture medium supplemented with human AB serum, phytohemagglutinin and bromodeoxyuridine. A high frequency of M₁ (first metaphase) cells was seen in cultures treated with a high dose (C ₁ = 1.0 g per culture) and in lymphocytes from donors in the age range 40–70 years. The delay in cell division and cell cycle kinetics may indicate a longer duration in DNA synthesis induced by trimethyltin chloride in aged lymphocytes.     

From START to FINISH: The Influence of Osmotic Stress on the Cell Cycle

The cell cycle is a sequence of biochemical events that are controlled by complex but robust molecular machinery. This enables cells to achieve accurate self-reproduction under a broad range of different conditions. Environmental changes are transmitted by molecular signalling networks, which coordinate their action with the cell cycle. The cell cycle process and its responses to environmental stresses arise from intertwined nonlinear interactions among large numbers of simpler components. Yet, understanding of how these pieces fit together into a coherent whole requires a systems biology approach. Here, we present a novel mathematical model that describes the influence of osmotic stress on the entire cell cycle of S. cerevisiae for the first time. Our model incorporates all recently known and several proposed interactions between the osmotic stress response pathway and the cell cycle. This model unveils the mechanisms that emerge as a consequence of the interaction between the cell cycle and stress response networks. Furthermore, it characterises the role of individual components. Moreover, it predicts different phenotypical responses for cells depending on the phase of cells at the onset of the stress. The key predictions of the model are: (i) exposure of cells to osmotic stress during the late S and the early G2/M phase can induce DNA re-replication before cell division occurs, (ii) cells stressed at the late G2/M phase display accelerated exit from mitosis and arrest in the next cell cycle, (iii) osmotic stress delays the G1-to-S and G2-to-M transitions in a dose dependent manner, whereas it accelerates the M-to-G1 transition independently of the stress dose and (iv) the Hog MAPK network compensates the role of the MEN network during cell division of MEN mutant cells. These model predictions are supported by independent experiments in S. cerevisiae and, moreover, have recently been observed in other eukaryotes.     

Locomotor Activity Rhythm in the Field Mouse Mus booduga Phase-shifts to Melatonin Injections in a Dose-dependent Manner

Melatonin is known to shift the phase of the locomotor activity rhythm in the field mouse Mus booduga in accordance with a type-I phase response curve (PRC), with phase delays during the subjective day and phase advances during late subjective night and the early subjective day. At CT4 (circadian time 4; i.e. 16 hr. after activity onset) and CT22 of the circadian cycle, a single dose of melatonin (1 mg/kg) is known to evoke maximum delay and maximum advance phase-shifts, respectively. We investigated the dose-dependent responses of the circadian pacemaker of these mice to a single dose of melatonin at the times for maximum delay and maximum advance. The circadian pacemaker responsible for the locomotor activity rhythm in these mice responded to various doses of melatonin in a dose-dependent manner with the magnitude of phase shifts increasing with dose.     

Locomotor Activity Rhythm in the Field Mouse Mus booduga Phase-shifts to Melatonin Injections in a Dose-dependent Manner

Melatonin is known to shift the phase of the locomotor activity rhythm in the field mouse Mus booduga in accordance with a type-I phase response curve (PRC), with phase delays during the subjective day and phase advances during late subjective night and the early subjective day. At CT4 (circadian time 4; i.e. 16 hr. after activity onset) and CT22 of the circadian cycle, a single dose of melatonin (1 mg/kg) is known to evoke maximum delay and maximum advance phase-shifts, respectively. We investigated the dose-dependent responses of the circadian pacemaker of these mice to a single dose of melatonin at the times for maximum delay and maximum advance. The circadian pacemaker responsible for the locomotor activity rhythm in these mice responded to various doses of melatonin in a dose-dependent manner with the magnitude of phase shifts increasing with dose.     

Effects of Actinomycin D on Generation Time and Morphogenesis in Paramecium*

SYNOPSIS. The sensitivity of Paramecium tetraurelia (=P. aurelia syngen 4) cells to pulse treatments with various doses of Actinomycin D (AMD) was estimated by comparing the generation times of treated and untreated sister cells. It was found that the delay of division in treated cells depended on the concentration of AMD, on their “age” at the time of the pulse treatment, and on their individual sensitivity. Sensitivity of Paramecium to AMD changes during the cell cycle in a predictable way. About 3 1/2 hr before the normally expected cell fission (total generation time ～ 5 1/2 hr) there is a decrease of sensitivity. Thereafter, the cell enters a new stage with a progressive increase of sensitivity. This 2nd phase ends at the “transition point” (～ 2 hr before cell division), when sensitivity drops abruptly. The division process itself may be altered and slowed down by high concentrations of AMD, even if the drug is applied after the transition point, but this process can never be completely annulled. The impairment of the division mechanism may lead to morphologic anomalies in the offspring. Resorption of oral anlagen in P. tetraurelia probably never occurs during the cell cycle after AMD treatment. The reason for individual variability of the cells, mechanisms controlling development, and the question of an obligate sequence of gene action in each cell cycle are discussed.     

Consequences of parental exposure to epidermal growth factor for progeny cell division

The consequences of parental exposure to epidermal growth factor (EGF), for progeny cell cycle times was investigated. Slowly dividing mouse 3T3 fibroblasts were exposed to EGF for 8 hr, the EGF was withdrawn, and the cell cycle times of parental and progeny cells were measured by time-lapse video microscopy. It was observed that exposure to EGF induced a round of cell division following a lag phase of approximately 8 hr. The progeny of these cells exhibited accelerated cell cycle times compared to cells that had not been exposed to EGF. Parental cell division time was significantly correlated with progeny cell cycle time. Sibling progeny cell cycle times were also significantly correlated. EGF can therefore apparently exert an effect on the cell cycle times of more than one generation of cells.     

Effects of Radiation,Antibiotics and Alkylating Agents on Cell Division and Growth in the Ciliate Spathidium spathula*

SYNOPSIS. Spathidium spathula is very sensitive to division inhibition after X-irradiation. Five kr delivered to animals 1 hr into the cell cycle prolong the period until the next division to about 2 times the normal length. The next 2 cell cycles, however, are shorter than normal, and by the 4th division irradiated cells have recovered the normal division rate. During this division delay, scanning interference microscopy shows that growth in dry mass continues; at the 1st post-irradiation division the cells average 3 times the normal dry mass. After the 2nd post-irradiation division, dry mass is 1.5 times the normal amount. Dry mass measurements were not made beyond the 2nd division. Giant cells produced by X-rays have enlarged macronuclei, indicating that DNA synthesis is not inhibited by a dose of X-rays that blocks division. Mitomycin C and triethylene melamine, agents which attack or damage DNA, also produce division blockage and giantism in Spathidium. This suggests that damage to DNA in either the macronucleus, the micronucleus or other organelles may be much more effective in delaying cell division than cell growth.     

Life Cycle Analysis of Mammalian Cells: III. The Inhibition of Division in Chinese Hamster Cells by Puromycin and Actinomycin

Analysis of the effects of actinomycin and puromycin on the G₂ and mitotic parts of the life cycle in Chinese hamster ovary cells grown in suspension and synchronized by thymidine treatment has been carried out. Rates of division of partially synchronized cell populations were measured in the presence and absence of the drugs, and various controls were performed to test for absence of complex side effects. Actinomycin produces a block 1.9 hr before completion of division, while puromycin produces a block almost coinciding with the initiation of mitosis. Evidence is presented that the puromycin block may be a double one, inhibiting one kind of protein synthesis that virtually coincides with the beginning of mitosis and another that occurs about 8 min earlier. The data are interpreted in terms of the time interval between messenger formation and its associated protein synthesis in this region of the life cycle. The various events studied have been provisionally mapped in the G₂ and mitotic periods of the life cycle.     

Radiation-induced mitotic delay: duration, dose and cell position dependence in the crypts of the small intestine in the mouse

The cells of the proliferative compartment in the crypt of the small intestine undergo a step by step differentiation and/or maturation from stem cells to the functional cells on the villi. The consequent hierarchical organization of the proliferative cell population can be related to the actual position of cells within the crypt. The stem cells are found near the bottom of the crypt with the more mature cells occurring at increasingly higher positions. The sensitivity of proliferative cells in the crypt of small intestine to radiation-induced mitotic delay was investigated at each position within the crypt. Using the stathmokinetic method (vincristine accumulation), the following were noted. The yield of mitotic figures 3 h immediately after irradiation showed a strong cell position dependence with the cells at the base of the crypt being most inhibited and those at the top of the proliferative compartment least affected. The mitotic yields were largely unaffected for the first 15 min suggesting that there is a transition point (Tp) for radiosensitivity which is located about 15 min before metaphase for all crypt cells. Cells located less than 15 min from metaphase are unaffected while those more than 15 min from metaphase are inhibited from further cell cycle progression. After this initial delay all proliferative cells were inhibited in their progression through G2 but some recovered more quickly than others. The ratio of the time of division delay (Td) in stem cells to that in cells at the top of the proliferative compartment was about 3:1. In absolute values Td after 1.0 Gy was about 1 h and 2.8 h, for cells at the top of the crypt and at the base, respectively. After 2.5 Gy the corresponding values were less than 3 h and between 5 and 6 h for the mid-crypt and crypt base respectively. There is thus a dependence on dose for the duration of the mitotic inhibition which for the cells at the top of the crypt is similar to the widely quoted average value 1 h per Gy, but the duration depends strongly on cell position. Thus not all proliferative cells respond in the same way. The duration is shorter the closer the proliferative cells are to their last cell division in the proliferative hierarchy in the crypt and longest for cells situated where the stem cells are to be expected.     

Onset of penicillin-induced bacteriolysis in staphylococci is cell cycle dependent.

Synchronously growing staphylococci were treated with "lytic" concentrations of penicillin at different stages of their division cycle. Coulter Counter measurements and light microscopy were used to determine the onset of bacteriolysis. Independent of the stage of the division cycle at which penicillin was added, (i) the cells were always able to perform the next cell division; (ii) the following division, however, did not take place; and (iii) instead, at this time, when the onset of the subsequent cell separation was observed in control cultures, lysis of the penicillin-treated cells occurred. These results support a recent model (P. Giesbrecht, H. Labischinski, and J. Wecke, Arch. Microbiol. 141:315-324, 1985) explaining penicillin-induced bacteriolysis of staphylococci as the result of a special morphogenetic mistake during cross wall formation.