5-AMINOURACIL TREATMENT : A Method for Estimating G2

Treatment of Vicia faba lateral roots with a range of concentrations of 5-aminouracil (5-AU) indicate that cells are stopped at a particular point in interphase. The timing of the fall in mitotic index suggests that cells are held at the S - G₂ transition. When cells are held at this point, treatments with 5-AU can be used to estimate the duration of G₂ + mitosis/2 of proliferating cells. Treatment with 5-AU can also be used to demonstrate the presence of subpopulations of dividing cells that differ in their G₂ duration. Using this method, 5-AU-induced inhibition, we have confirmed that in V. faba lateral roots there are two populations of dividing cells: (a) a fast-dividing population, which makes up ~85% of the proliferating cell population and has a G₂ + mitosis/2 duration of 3.3 hr, and (b) a slow-dividing population, which makes up ~15% of dividing cells and has a G₂ duration in excess of 12 hr. These estimates are similar to those obtained from percentage labeled mitosis (PLM) curves after incorporation of thymidine-³H.     

ON THE EXISTENCE OF A Go-PHASE IN THE CELL CYCLE

The model is based on the assumption that the cell cycle contains a G_o-phase which cells leave randomly with a constant probability per unit time, γ. After leaving the G_o-phase, the cells enter the C-phase which ends with cell division. The C-phase and its constituent phases, the‘true’G₁-phase, the S-phase, the G₂-phase and mitosis are assumed to have constant durations of T, T₁T_s, T₂ and T_m, respectively. For renewal tissue it is assumed that the probability per unit time of being lost from the population is a constant for all cells irrespective of their position in the cycle. The labelled mitosis curve and labelling index for continuous labelling are derived in terms of γ, T, and T_s. The model generates labelled mitosis curves which damp quickly and reach a constant value of twice the initial labelling index, if the mean duration of the G_o-phase is sufficiently long. It is shown that the predicted labelled mitosis and continuous labelling curves agree reasonably well with the experimental curves for the hamster cheek pouch if T has a value of about 60 hr. Data are presented for the rat dorsal epidermis which support the assumption that there is a constant probability per unit time of a cell being released from the Go-phase.     

Cell cycle analysis of tumour-derived cultures ofCrepis capillaris: A kinetic analogy with proliferation of animal tumour cells

Summary Analysis of the cell cycle by three methods has revealed unusual kinetics of proliferation in tumour derived suspensions ofCrepis capillaris. The different methods of analysis yield different estimates of cycle phase durations, and such discrepancies have been explained in terms of low growth fractions with rapid total cycle traverse. Specifically, confidence in the estimation of G₂ duration by the fraction of labelled mitosis analysis, and comparison with shorter G₂ estimates obtained by the two other methods, suggests that cells drop out in G₁. However, cells which do not drop out of the proliferative compartment traverse G₁ extremely rapidly. Extremely short cell cycle durations in which the G₁ phase is virtually non-existent are uncharacteristic of plant cell suspension cultures, in which the G₁ phase has previously been shown to be extended as compared with meristematic root tip cells. A model has been proposed in which a central core of rapidly dividing cells continuously loses cells into a subpopulation of resting or G₀ cells with the G₁ DNA content. Similarities between plant and animal tumours with respect to cell growth and division are discussed.     

Occurrence of two cell subpopulations with different cell-cycle durations in the central and peripheral zones of the vegetative shoot apex of Sinapis alba L.

The cell-cycle duration and the growth fraction were estimated in the vegetative shoot apical meristem of Sinapis alba L. The length of the cell cycle was about 86 h, i.e. 2.5 times shorter than the cell-doubling time (M. Bodson, 1975, Ann. Bot. 39, 547–554) and the growth fraction was between 32 to 41%. These data demonstrated that the cell population of this meristem was heterogeneous, including one subpopulation of rapidly cycling cells and one subpopulation of non-cycling cells, i.e. cells with a very long cell cycle compared with that of the rapidly cycling cells. Non-cycling cells had no particular localization within the meristem. Both the central and peripheral zones of the meristem were mosaics of rapidly cycling and non-cycling cells.Abbreviations G₁ pre-DNA-synthesis phase - G₂ post-DNA-synthesis phase - GF growth fraction - M mitosis phase - PLM pulse-labelled-mitoses method - S DNA-synthesis phase - T cell-cycle duration - TdR thymidine     

Reversible accumulation of plant suspension cell cultures in g(1) phase and subsequent synchronous traverse of the cell cycle

The induction of DNA synthesis in Datura innoxia Mill. cell cultures was determined by flow cytometry. A large fraction of the total population of cells traversed the cell cycle in synchrony when exposed to fresh medium. One hour after transfer to fresh medium, 37% of the cells were found in the process of DNA synthesis. After 24 hours of culture, 66% of the cells had accumulated in G₂ phase, and underwent cell division simultaneously. Only 10% of the cells remained in G₀ or G₁. Transfer of cells into a medium, 80% (v/v) of which was conditioned by a sister culture for 2 days, was adequate to inhibit this simultaneous traverse of the cell cycle. A large proportion of dividing cells could be arrested at the G₀ + G₁/S boundary by exposure to 10 millimolar hydroxyurea (HU) for 12 to 24 hours. Inhibition of DNA synthesis by HU was reversible, and when resuspended into fresh culture medium synchronized cells resumed the cell cycle. Consequently, a large fraction of the cell population could be obtained in the G₂ phase. However, reversal of G₁ arrested cells was not complete and a fraction of cells did not initiate DNA synthesis. Seventy-four percent of the cells simultaneously reached 4C DNA content whereas the frequency of cells which remained in G₀ + G₁ phase was approximately 17%. Incorporation of radioactive precursors into DNA and proteins identified a population of nondividing cells which represents the fraction of cells in G₀. The frequency of cells entering G₀ was 11% at each generation. Our results indicate that almost 100% of the population of dividing cells synchronously traversed the cell cycle following suspension in fresh medium.     

Effect of nickel at high concentration on proliferation of quiescent center cells and initiation of lateral root primordia in wheat seedlings

DNA synthesis and cell divisions in the quiescent center as well as initiation of lateral root primordia were investigated in the course of incubation of the roots of 3-day-old wheat (Triticum aestivum L.) seedlings on the medium with 0.1 mM NiSO₄ for 72 h. It was found that the earliest effect of nickel on proliferation of the quiescent center cells was associated with an increase in the mitotic index 6 h after the beginning of its action. This effect was assumed to depend on an increase in mitosis time. Twelve hours after the beginning of the effect of nickel, mitotic index became somewhat lower, and in 18 h it sharply decreased. Some dividing cells were observed among the initial cells of certain tissues and near the quiescent center even in 72 h. The portion of DNA synthesizing cell sharply decreased in 12 h, and in 48 h such cells were lacking. The main mechanism governing the termination of cell proliferation in the quiescent center as well as in the meristem and calyptrogen of the cap is the inhibition of cell transition to DNA synthesis. The cells that had time to start DNA synthesis or already finished it and were in other phases of the cycle continued a slow progression through the cycle and completed it. Sister cells, produced as a result of divisions, left the mitotic cycle in the phase G₁ and transited to dormancy. Nickel did not inhibit initiation and development of lateral root primordia. Resumption of DNA synthesis and cell divisions occurred not only in the pericycle and endodermis participating in the initiation of lateral root primordia but also in the cortex cells in the vicinity of developing primordia. In 18 h after the beginning of the experiment when the rate of the root growth considerably decreased, the region, where primordia were initiated, was located closer to the root tip. Subsequently, when elongation of the cells was inhibited, this region moved closer to the tip until structural disturbances occurred in the nuclei of the endodermal cells located near the root tip and elongated under the effect of nickel. The results concerning the effect of nickel and other heavy metals on root cell proliferation obtained by other researchers and the role of pericycle organization in the translocation and accumulation of nickel in the tissues are discussed.     

THE MECHANISM OF 5-AMINOURACIL-INDUCED SYNCHRONY OF CELL DIVISION IN VI CIA FABA ROOT MERISTEMS

Cessation of mitosis was brought about in Vicia faba roots incubated for 24 hours in the thymine analogue, 5-aminouracil. Recovery of mitotic activity began 8 hours after removal from 5-aminouracil and reached a peak at 15 hours. If colchicine was added 4 hours before the peak of mitoses, up to 80 per cent of all cells accumulated in mitotic division stages. By use of single and double labeling techniques, it was shown that synchrony of cell divisions resulted from depression in the rate of DNA synthesis by 5-aminouracil, which brought about an accumulation of cells in the S phase of the cell cycle. Treatment with 5-aminouracil may have also caused a delay in the rate of exit of cells from the G₂ period. It appeared to have no effect on the duration of the G₁ period. When roots were removed from 5-aminouracil, DNA synthesis resumed in all cells in the S phase. Although thymidine antagonized the effects of 5-aminouracil, an exogenous supply of it was not necessary for the resumption of DNA synthesis, as shown by incorporation studies with tritiated deoxycytidine.     

EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE RADIATIONS ON CELL CYCLE KINETICS IN EXCISED ROOT MERISTEMS OF PISUM SATIVUM

Near-ultraviolet and visible radiations increased the duration of the mitotic cycle in excised pea root meristems primarily by lengthening the duration of the pre-DNA synthetic period (G₁). All radiations tested shortened the duration of the post-DNA synthetic period (G₂). The most pronounced effects were exhibited by green radiation, which lengthened the duration of the cell cycle, G₁, DNA synthesis (S), and mitosis (M), and shortened the duration of G₂. Progression of cells arrested by starvation in G₁ and G₂ into DNA synthesis and mitosis was also affected by light treatments. Green radiation appeared to arrest a group of cells in DNA synthesis as well as in G₁ and G₂. Meristems receiving green and near-ultraviolet radiations exhibited the most rapid progression of G₁ cells through S and G₂.     

The effect of ethylene on root meristems of Pisum sativum and Zea mays

Summary Ethylene at a concentration of 100 l l^–1 causes a slight increase in the duration of the mitotic cycle in the primary root meristems of both Pisum sativum L. and Zea mays L. This is due to a lengthening of the G ₁ phase; other phases of the cycle are unaffected. Autoradiography and microdensitometry show that the rate of ³H-thymidine incorporation into nuclei of Pisum is maximal when about half the DNA has been replicated, and that ethylene has no effect upon this rate. Ethylene causes a reduction of the number of dividing cells in the root meristem, particularly in Pisum.Abbreviations Duration of the S phase, the G ₁ phase, the G ₂ phase of the mitotic cell cycle, respectively - T _C Duration of the complete mitotic cell cycle - QC Quiescent centre - LI, MI Labelling index, Mitotic index (i.e. fraction of the population labelled or in mitosis, respectively) - PF Proliferative fraction (i.e. fraction of the population making progress towards mitosis) - [³H]dT tritiated thymidine     

REGENERATIVE PROLIFERATION OF MOUSE EPIDERMAL CELLS FOLLOWING ADHESIVE TAPE STRIPPING

The proliferating cells of mouse epidermis (basal cells) can be separated from the non-proliferating cells (differentiating cells) (Laerum, 1969) and brought into a mono-disperse suspension. This makes it possible to determine the cell cycle distributions (e.g. the relative number of cells in the G^ S and (G₂+ M) phases of the cell cycle) of the basal cell population by means of micro-flow fluorometry. To study the regenerative cell proliferation in epidermis in more detail, changes in cell cycle distributions were observed by means of micro-flow fluorometry during the first 48 hr following adhesive tape stripping. ³H-TdR uptake (LI and grain count distribution) and mitotic rate (colcemid method) were also observed. An initial accumulation of G₂ cells was observed 2 hr after stripping, followed by a subsequent decrease to less than half the control level. This was followed by an increase of cells entering mitosis from an initial depression to a first peak between 5 and 9 hr which could be satisfactorily explained by the changes in the G₂ pool. After an initial depression of the S phase parameters, three peaks with intervals of about 12 hr followed. The cells in these peaks could be followed as cohorts through the G₂ phase and mitosis, indicating a partial synchrony of cell cycle passage, with a shortening of the mean generation time of basal cells from 83-3 hr to about 12 hr. The oscillations of the proportion of cells in G₂ phase indicated a rapid passage through this cell cycle phase. The S phase duration was within the normal range but showed a moderate decrease and the Gj phase duration was decreased to a minimum. In rapidly proliferating epidermis there was a good correlation between change in the number of labelled cells and cells with S phase DNA content. This shows that micro-flow fluorometry is a rapid method for the study of cell kinetics in a perturbed cell system in vivo.     

Effects of 1000 R whole-body X-irradiation on DNA synthesis and mitosis in the duodenal crypts of the BCF1 mouse

Summary Effects of 1000 R, whole-body X-irradiation on the proliferative cells of the mouse duodenal crypts, in the four phases of the generation cycle; namely, the DNA synthesis phase, S; the pre-mitotic gap, G ₂; the division phase or mitosis, M; and the pre-synthesis gap, G ₁. As pointed out by Whitmore and Till (1964) G₁ and G₂ are characterized only by the fact that no DNA synthesis is taking place in these phases.In the intestinal crypts of BCF₁ mice, a 1000 R whole-body X-ray exposure blocks cells in G₂ for approximately 18 hours, and reduces the number of cells in S to less than 1/2 that observed in control animals during the first 12 hours after exposure. Cells synthesizing DNA, and undergoing division, remain few in number for more than 48 hours. Between 48 and 72 hours a compensatory reaction begins, and the number of cells in M and S increases from 28 at 48 hours to 150 at 72 hours and reaches a mean value of 482 at 96 hours.Work supported under the auspices of the US Atomic Energy Commission.     

Growth dynamics of an amphibian tissue

By the “labeled mitoses” method of Quastler and Sherman and others, the cell cycle of the germinative zone cells of the bullfrog lens epithelium has been characterized. It has been shown that this cycle lasts approximately 83 days with the DNA synthetic phase enduring 100 hours and G₂, 11 hours. G₁ occupies over 90% of the total time. the duration of mitosis itself has not been precisely determined. the length of the synthetic phase was corroborated by double labeling with c¹⁴ and h³-thymidine. When the temperature is raised by 6°c, from 24° to 30° the cycle is compressed by 40%. When the nongerminative, central cells of bullfrog lens epithelium are activated (stimulated to undergo DNA synthesis and mitosis) by injury or through in vitro culture, the length of the cycle also appears to decrease. in the in vitro experiments the generation time, as judged by the period elapsing between two successive bursts of DNA synthesis involving the same cells, amounts to 177–190 hours at 24°c. by raising the temperature to 30°c the time from injury or isolation until the appearance of the first wave of mitosis is reduced by 20%.     

Duration of the nuclear cycle in Tradescantia root tips at three temperatures as measured with H-thymidine

The duration of the subdivisions of the nuclear cycle in cells from the root tips of Tradescantia paludosa was determined by the labelled mitosis method. These times were found not to increase or decrease in direct proportion to each other at the three temperatures tested, 13, 21 and 30 C. The main difference between the nuclear cycles at 30 and 21 C was in the shortening of the pre-DNA synthetic period (G₁) at the higher temperature. A comparison between the nuclear cycle at 21 and 13 C showed that at the lower temperature mitosis and the post-DNA synthetic period (G₂) were approximately tripled in duration while DNA synthesis was doubled. Cell synchronization and radiosensitivity are discussed in relation to these findings.     

Duration of the Mitotic Cycle in Cell Cultures of Haplopappus gracilis

The duration of the cell cycle and its component phases in cell cultures of Haplopappus gracilis was estimated by means of pulse labelling with tritiated thymidine and subsequent autoradiographic techniques. The total duration of the mitotic cycle was found to be 22.0 hours. The average durations of the following component phases were: the synthetic period (S) 6.4 hours, the postsynthetic period (G₂) 4.86 hours, prophase (P) 0.64 hours, metaphase (M) 0.40 hours, anaphase + early telophase (AT) 0.36 hours, the presynthetic period (G₁) 9.34 hours. The results indicate that G₁ and G₂ are the phases, which are most prolonged in populations of cultivated cells when compared to the same phases in root lip cells from the same species.     

Existence of a commitment program for mitosis in early G1 in tumour cells

The proliferation of normal non-tumourigenic mouse fibroblasts is stringently controlled by regulatory mechanisms located in the postmitotic stage of G₁ (which we have designated G₁ pm). Upon exposure to growth factor depletion or a lowered de novo protein synthesis, the normal cells leave the cell cycle from G₁ pm and enter G₀. The G₁ pm phase is characterized by a remarkably constant length (the duration of which is 3 h in Swiss 3T3 cells), whereas the intercellular variability of intermitotic time is mainly ascribable to late G₁ or pre S phase (G₁ ps) (Zetterberg & Larsson (1985) Proc. Natl. Acad. Sci. USA 82 , 5365). As shown in the present study two tumour-transformed derivatives of mouse fibroblasts, i.e. BPA31 and SVA31, did not respond at all, or only responded partially, respectively, to serum depletion and inhibition of protein synthesis. If the tumour cells instead were subjected to 25-hydroxycholesterol (an inhibitor of 3-hydroxy-3 methyglutaryl coenzyme A reductase activity), their growth was blocked as measured by growth curves and [³H]-thymidine uptake. Time-lapse analysis revealed that the cells were blocked specifically in early G₁ (3-4h after mitosis), and DNA cytometry confirmed that the arrested cells contained a G₁ amount of DNA. Closer kinetic analysis revealed that the duration of the postmitotic phase containing cells responsive to 25-hydroxycholesterol was constant. These data suggest that transformed 3T3 cells also contain a ‘G₁ pm program’, which has to be completed before commitment to mitosis. By repeating the experiments on a large number of tumour-transformed cells, including human carcinoma cells and glioma cells, it was demonstrated that all of them possessed a G₁ pm-like stage. Our conclusion is that G₁ pm is a general phenomenon in mammalian cells, independent of whether the cells are normal or neoplastic.     

Sister chromatid exchanges occur in G2-irradiated cells

DNA double-strand breaks (DSBs) are arguably the most important lesions induced by ionizing radiation (IR) since unrepaired or misrepaired DSBs can lead to chromosomal aberrations and cell death. The two major pathways to repair IR-induced DSBs are non-homologous end-joining (NHEJ) and homologous recombination (HR). Perhaps surprisingly, NHEJ represents the predominant pathway in the G₁ and G₂ phases of the cell cycle, but HR also contributes and repairs a subset of IR-induced DSBs in G₂. Following S-phase-dependent genotoxins, HR events give rise to sister chromatid exchanges (SCEs), which can be detected cytogenetically in mitosis. Here, we describe that HR occurring in G₂-irradiated cells also generates SCEs in ∼50% of HR events. Since HR of IR-induced DSBs in G₂ is a slow process, SCE formation in G₂-irradiated cells requires several hours. During this time, irradiated S-phase cells can also reach mitosis, which has contributed to the widely held belief that SCEs form only during S phase. We describe procedures to measure SCEs exclusively in G₂-irradiated cells and provide evidence that following IR cells do not need to progress through S phase in order to form SCEs.Key words: sister chromatid exchanges, double-strand break repair, ionizing radiation, homologous recombination, G₂ phase     

The time and duration of the premeiotic inteprhase in microsporocytes ofTrillium kamtschaticum

The time and duration of each phase of the premeiotic interphase were determined in microsporocytes of two clones (S and K clones) ofTrillium kamtschaticum. After collectionTrillium plants were stored at 3 C or 7 C prior to completion of premeiotic mitosis in archesporial cells. For autoradiography, cells were explanted in the presence of³H-thymidine to identify the interval of the premeiotic DNA synthesis. Approximate durations of the G₁, S and G₂ phases for the K clone stored at 3 C were estimated to be 12, 12 and 14 days, respectively. The interval of premeiotic development was markedly different between clones. A high degree of synchrony in meiotic development, which is usually observed within anthers up to late meiotic prophase, was confirmed at the S phase, suggesting that synchrony is established during the G₁ interval.     

Arrest of Chinese hamster cells in G 2 following treatment with the anti-tumor drug bleomycin

Upon addition of bleomycin (BLM) to suspension cultures of Chinese hamster cells (line CHO), cells closer to prophase than 56 minutes continue dividing at the normal rate, whereas cells at earlier positions in the cell cycle either fail to reach mitosis altogether (at 200 μg/ml) or enter mitosis and divide at a reduced rate at lower drug concentrations. At 100 μg/ml of BLM (the rate of cell division slowed to a doubling time of 167 hours), initiation and termination of DNA synthesis occur at normal rates, resulting in an accumulation of cells with a G₂ DNA content in the first 130 minutes of G₂. Bleomycin effects are not readily reversible. The rates of incorporation of leucine, uridine, or thymidine into cells treated for six hours with 100 μg/ml of BLM were 90, 85, and 80%, respectively, of the values obtained in control cultures, suggesting that the effects of BLM on cell-cycle traverse cannot be correlated with gross inhibition of macromolecular synthesis.     

Heterogeneity in Cell Behaviour in Primordia ofVicia faba

The response of cells of small primordia ofVicia faba to³H-TdR and colchicine is discussed. The delayed uptake of³H-TdR shown by cells of small primordia appears to be a property of only 50% of the cells; the remaining never become capable of incorporating³H-TdR. Prom the labeled cells and polyploid cells induced by colchicine the shortest cycle time in small primordia is estimated to be 12 hours. Within a period equal to 1 mitotic cycle, 31–35% of all mitoses are tetraploid, following treatment with colchicine. The remainder are diploid and diploid mitoses were seen for up to 30 hours. These observations are indicative of a heterogeneity for mitotic cycle time in populations consisting of up to 1,500 cells. The percentage labeled mitosis curve of diploid cells was changed in primordia treated with colchicine; higher peaks were found. These results show that even small populations of cells, at the beginning of a morphogenetic system, are very heterogeneous for key cell properties. This research has been supported by the U.S.A.B.C. [AT (11-1) 1625-21].     

Lack of Mitotic Delays at the Onset of Proliferation in Dormant Root Primordia Challenged by Ionizing Radiation

X-rays at doses between 2.5 and 20 Gy were applied to Allium cepa L. bulbs containing either dormant root primordia (before water imbibition) or actively proliferating meristems. Irradiation of the primordia that were enriched in G₀ cells neither delayed proliferation onset nor root sprouting. Under both protocols, irradiation decreased the final length of the roots to about 60 % (at 20 Gy) of that reached by the unirradiated controls. Irradiation of the proliferating meristems increased the mitotic index at some fixation times. This could not be due to a rise in the cell entry into mitosis, as the rate of root growth decreased simultaneously. The increased mitotic index should be the consequence of a delay in the relative time taken by mitosis in the whole cycle time. Lengthened mitosis probably allows the post-replicative repair of most DNA lesions, as the frequency of interphases with micronuclei was higher in the cells which were irradiated when still dormant than in those irradiated when cycling. Thus, the mitotic delays should be the consequence of a checkpoint pathway activated by the presence of DNA damage. This feedback mechanism seems only to develop after cell proliferation is restored. This revised version was published online in July 2006 with corrections to the Cover Date.