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.     

Heterogeneity in the mouse epidermal cell cycle analysed by computer simulations

Abstract. Different sets of cell kinetic data obtained over many years from hairless mouse epidermis have been simulated by a mathematical model including circadian variations. Simulating several independent sets of data with the same mathematical model strengthens the validity of the results obtained. The data simulated in this investigation were all obtained with the experimental system in a state of natural synchrony. The data include cell cycle phase distributions measured by DNA flow cytometry of isolated epidermal basal cells, fractions of tritiated thymidine ([³H]TdR) labelled cells within the cell cycle phases measured by cell sorting at intervals after [³H]TdR pulse labelling, bivariate bromodeoxyuridine (BrdUrd)/DNA data from epidermal basal cells isolated at intervals after pulse labelling with BrdUrd, mitotic rate and per cent labelled mitosis (PLM) data from histologic sections. The following main new findings were made from the simulations: the second PLM peak observed at about 35 h after pulse labelling is hardly influenced by circadian variations; the peak is mainly determined by persisting synchrony of a rapidly cycling population with a G₁-duration (T_G1) of 20 h to 30 h; and there is a highly significant population of slowly cycling G₁-cells (G_1σ). However, no significant circadian variations were found in the number of these cells.     

CIRCADIAN RHYTHMS IN MOUSE EPIDERMAL BASAL CELL PROLIFERATION

Several kinetic parameters of basal cell proliferation in hairless mouse epidermis were studied, and all parameters clearly showed circadian fluctuations during two successive 24 hr periods. Mitotic indices and the mitotic rate were studied in histological sections; the proportions of cells with S and G₂ phase DNA content were measured by flow cytometry of isolated basal cells, and the [³H]TdR labelling indices and grain densities were determined by autoradiography in smears from basal cell suspensions. The influx and efflux of cells from each cell cycle phase were calculated from sinusoidal curves adapted to the cell kinetic findings and the phase durations were determined. A peak of cells in S phase was observed around midnight, and a cohort of partially synchronized cells passed from the S phase to the G₂ phase and traversed the G₂ phase and mitosis in the early morning. The fluctuations in the influx of cells into the S phase were small compared with the variations in efflux from the S phase and the flux through the subsequent cell cycle phases. The resulting delay in cell cycle traverse through S phase before midnight could well account for the accumulation of cells in S phase and, therefore, also the subsequent partial synchrony of cell cycle traverse through the G₂ phase and mitosis. Circadian variations in the duration of the S phase, the G₂ phase and mitosis were clearly demonstrated.     

ACTIVITY OF TUBULOSINE ON THE KINETICS OF ROOT MERISTEM CELL POPULATION

The action of tubulosine on the mitotic cycle was studied using continuous labelling with tritiated thymidine. This alkaloid provokes a lengthening of the G₁ and S phases and a blocking of G₂ is totally reversible when the treatment is followed by recovery in normal medium. At a dose of tubulosine which induces a reversible mitostasis in the shortest possible time the lengthening of the phases of the cell cycle was estimated by three different techniques: labelled mitoses for the determination of G₂; labelling intensity for the determination of S; binucleate cells for the determination of T, and an original technique using labelling index of binucleate cells for the determination of G₁. The limits of the technique of labelled mitosis together with the interest of the technique aiming at the direct determination of G₁ in the case of a perturbed cycle are then discussed.     

Effects of Pulse Labelling With Tritiated Thymidine On the Circadian Rhythmicity In Epidermal Cell-Cycle Distribution In Mice

The influence of pulse labelling with 50 °Ci tritiated thymidine ([³H]TdR) (2 μCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G₂ phases of the cell cycle were estimated from the obtained DNA frequency distributions. the proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [³H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [³H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G₂ and M phase during the first 32 hr after the injection. the number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 °Ci [³H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

Repeated injection (continuous labelling) experiments in mouse epidermis

Theoretical labelling index curves for epidermis have been generated under conditions of repeated tritiated thymidine injection. These curves take into account different injection intervals, circadian fluctuations in labelling and two different models for epidermal proliferation; one based on a homogeneous basal layer with “random” loss initially (later, loss was restricted to late G₁), and the other based on a programmed sequential aging of proliferative cells in a compartment derived from a minority class of stem cells. These curves have been compared with previously published experimental results and with results from some new experiments. Both models fit the data to some extent provided a mean value of T_c of about 140 h is assumed. However, the sequential aging model provides a slightly better overall fit. A further conclusion is that it is impossible to make any accurate statements on the epidermal growth fraction from repeated labelling data.     

Mathematical model analysis of mouse epidermal cell kinetics measured by bivariate DNA/anti-bromodeoxyuridine flow cytometry and continuous [3H]-thymidine labelling

Abstract. In a previous study the epidermal cell kinetics of hairless mice were investigated with bivariate DNA/anti-bromodeoxyuridine (BrdU) flow cytometry of isolated basal cells after BrdU pulse labelling. The results confirmed our previous observations of two kinetically distinct sub-populations in the G₂ phase. However, the results also showed that almost all BrdU-positive cells had left S phase 6–12 h after pulse labelling, contradicting our previous assumption of a distinct, slowly cycling, major sub-population in S phase. The latter study was based on an experiment combining continuous tritiated thymidine ([³H]TdR) labelling and cell sorting. The purpose of the present study was to use a mathematical model to analyse epidermal cell kinetics by simulating bivariate DNA/BrdU data in order to get more details about the kinetic organization and cell cycle parameter values. We also wanted to re-evaluate our assumption of slowly cycling cells in S phase. The mathematical model shows a good fit to the experimental BrdU data initiated either at 08.00 hours or 20.00 hours. Simultaneously, it was also possible to obtain a good fit to our previous continuous labelling data without including a sub-population of slowly cycling cells in S phase. This was achieved by improving the way in which the continuous [³H]TdR labelling was simulated. The presence of two distinct sub-populations in G₂ phase was confirmed and a similar kinetic organization with rapidly and slowly cycling cells in G₁ phase is suggested. The sizes of the slowly cycling fractions in G₁ and G₂ showed the same distinct circadian dependency. The model analysis indicates that a small fraction of BrdU labelled cells (3–5%) was arrested in G₂ phase due to BrdU toxicity. This is insignificant compared with the total number of labelled cells and has a negligible effect on the average cell cycle data. However, it comprises 1/3 to 1/2 of the BrdU positive G₂ cells after the pulse labelled cells have been distributed among the cell cycle compartments.     

Cell kinetic studies in the murine ventral tongue epithelium: thymidine metabolism studies and circadian rhythm determination

Abstract.  The oral mucosa is a rapidly replacing body tissue that has received relatively little attention in terms of defining its cell kinetics and cellular organization. The tissue is sensitive to the effects of cytotoxic agents, the consequence of which can be stem cell death with the subsequent development of ulcers and the symptoms of oral mucositis. There is considerable interest in designing strategies to protect oral stem cells and, hence, reduce the mucositis side-effects in cancer therapy patients. Here we present details of a new histometric approach designed to investigate the changing patterns in cellularity in the ventral tongue mucosa. This initial paper in a series of four papers presents observations on the changing patterns in the labelling index following tritiated thymidine administration, which suggest a delayed uptake of tritiated thymidine from a long-term intracellular thymidine pool, a phenomenon that will complicate cell kinetic interpretations in a variety of experimental situations. We also provide data on the changing pattern of mitotic activity through a 24-h period (circadian rhythms). Using vincristine-induced stathmokinesis, the data indicate that 54% of the basal cells divide each day and that there is a high degree of synchrony in mitotic activity with a mitotic peak occurring around 13.00 h. The mitotic circadian peak occurs 9-12 h after the circadian peak in DNA synthesis. The data presented here and in the subsequent papers could be interpreted to indicate that basal cells of BDF1 mice have an average turnover time of about 26-44 h with some cells cycling once a day and others with a 2- or 3-day cell cycle time.     

CELL POPULATION KINETICS OF EXCISED ROOTS OF PISUM SATIVUM

The cell population kinetics of excised, cultured pea roots was studied with the use of tritiated thymidine and colchicine to determine (1) the influence of excision, (2) the influence of sucrose concentration, (3) the average mitotic cycle duration, and (4) the duration of mitosis and the G₁, S, and G₂ periods of interphase.¹ The results indicate that the process of excision causes a drop in the frequency of mitotic figures when performed either at the beginning of the culture period or after 100 hours in culture. This initial decrease in frequency of cell division is independent of sucrose concentration, but the subsequent rise in frequency of division, after 12 hours in culture, is dependent upon sucrose concentration. Two per cent sucrose maintains the shortest mitotic cycle duration. The use of colchicine indicated an average cycle duration of 20 hours, whereas the use of tritiated thymidine produced an average cycle duration of 17 hours.     

CELL KINETICS IN THE SEBACEOUS GLANDS OF THE MOUSE. I. THE GLANDS IN RESTING SKIN

Cell proliferation, differentiation and migration have been studied in the sebaceous glands of DBA-2 mice in the resting (telogen) phase of hair growth. Cells labelled by a single injection of tritiated thymidine start to leave the glands of adult male mice 5 days later. About 80% of the proliferative cells in the basal layer have a cell cycle time of 40 hr or less. In 18% of the proliferative cells G₁ is at least 4 days long and 16% have a G₂ phase longer than 17 hr. The S phase is about 7.5 hr long and cells spend at least 21 hr in the basal layer before migrating into the differentiating cell region. The glands of mature female and immature mice are smaller than those of the mature male. They have fewer, smaller cells and a much lower labelling index.     

Estimation of Circadian Variations In Cell Cycle Phase Durations In Murine Epidermal Basal Cells

Circadian variations in the proliferative activity of squamous epithelia are well known. However, circadian variations in the duration of the various cell cycle phases (S, G₂ and mitosis) have been disputed. the percent labelled mitoses method, which is traditionally used to obtain duration of cell cycle phases, is poorly suited for identification of circadian variations. Therefore methods combining changes in compartment size (cell cycle phase) and cellular flux through the compartments have been used. Three different methods using such data are presented. These incorporate various simplifying assumptions that cause methodological errors. Limits for use of the different methods are indicated. the use of all three methods gives comparable and pronounced circadian variations in the duration of S and G₂ phase. These results are also compatible with circadian variations in the mitotic duration, but they may also represent artefacts due to sensitivity to model errors.     

Effects of pulse labelling with tritiated thymidine on the circadian rhythmicity in epidermal cell-cycle distribution in mice

The influence of pulse labelling with 50 microCi tritiated thymidine ( [3H]TdR) (2 microCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G2 phases of the cell cycle were estimated from the obtained DNA frequency distributions. The proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [3H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [3H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G2 and M phase during the first 32 hr after the injection. The number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 microCi [3H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

Turnover and maturation kinetics in the hairless mouse epidermis. Continuous [3H]TdR labelling and mathematical model analyses

Hairless mice were continuously labelled with 10 microCi of tritiated thymidine ([3H]TdR) every 4 h for 8 d, and the proportions of labelled basal and differentiating cells were recorded separately. The mitotic rate was measured by the stathmokinetic method and the cell cycle distributions were measured by flow cytometry of isolated basal cells at intervals during the labelling period. The mitotic rate of the [3H]TdR-injected animals did not deviate from control values during the first 5 d. Computer simulations of the data based on various mathematical models were made, and three main conclusions were obtained: (1) a large spread in transit times through the G1 phase was found, together with a very narrow distribution in maturation time of differentiating cells; (2) about 20% of the differentiating cells were estimated to leave the basal cell layer directly after mitosis. This is consistent with results obtained from different sets of data; and (3) during continuous labelling more than 90% of the cells are labelled during each passage through the S phase.     

Some Characteristics of DNA Synthesis and the Mitotic Cycle in Ehrlich Ascites Tumor Cells

In vivo studies of Ehrlich ascites tumor cells during the first 5 days of growth in peritoneal cavities of mice consisted of the following: 1. Determination of growth curves by direct enumeration of cells. 2. Estimation of the duration of each phase of the mitotic cycle based on incidence of cells in different phases. 3. Radioautographic studies to determine the proportion of cells in different phases of the mitotic cycle that incorporate tritiated thymidine during a single brief exposure to this precursor of DNA. 4. Estimation of the rate of incorporation of tritiated thymidine at different times during the period of DNA synthesis by comparison of mean grain counts over nuclei in radioautographs at different times following exposure to tritiated thymidine. The assumptions underlying these experiments and our observations concerning the duration of the period of DNA synthesis and its relation to the mitotic cycle are discussed. It is concluded that DNA synthesis is continuous, occupying a period of 8.5 hours during the interphase and that the average rate of synthesis is approximately constant.     

The duration of DNA synthetic (S) period in Zea mays: A genetic control

Summary The nuclear cycle among several diverse genetic stocks of Zea mays root meristem cells was compared and it was found that there were no significant differences among the nuclear cycle durations and its component phases. The durations of various periods of their mitotic cycles were studied by autoradiography of cells pulse-labelled with tritiated thymidine (3H-TdR). The total nuclear cycle was 10 to 11.5 hours and mitosis was 0.81 to 1.34 hours at 25°C. The S period is the longest interval (50% of the total time) of the nuclear cycle; of the rest of the cycle, G₂ is longer than G₁ or mitosis among all stocks. The constancy of the nuclear cycle among several stocks was adduced as evidence for strict genetic control of the cycle. Furthermore, it is demonstrated the DNA synthesis period is not dependent upon the amount of DNA present.This study is based on a portion of the dissertation presented by the senior author to the Graduate School, The University of Western Ontario, London, Canada, in partial fulfillment of the requirement for the Ph. D. degree     

CELL POPULATION KINETICS OF PLUCKED AND UNPLUCKED MOUSE SKIN I. UNIRRADIATED SKIN

A detailed study of the cellular proliferation kinetics in interfollicular plucked and unplucked mouse skin has been made in Swiss albino mice, using tritiated thymidine autoradiography. Diurnal variations in mitotic and labelling indices were demonstrated in both systems.
The mean cell cycle times for unplucked and plucked skin were estimated by four different methods and found to be 100 ± 10 and 47 ± 3 hr respectively. Most of the difference was due to the shortening of G₁ phase after plucking. Repeated labelling at intervals shorter than the DNA synthesis times resulted in all the basal layer cells becoming labelled, so that the growth fraction was unity, in unplucked and plucked skin.
A well-defined second wave of labelled mitoses was seen at about 100 hr after labelling the unplucked (i.e. normal) mouse skin.
A double labelling technique using ¹⁴C-TdR and ³H-TdR with a single layer of emulsion gave reasonable values for the duration of the DNA synthesis phase.     

Turnover and Maturation Kinetics In the Hairless Mouse Epidermis. Continuous [3H]Tdr Labelling and Mathematical Model Analyses

Abstract. Hairless mice were continuously labelled with 10μCi of tritiated thymidine ([³H]TdR) every 4 h for 8 d, and the proportions of labelled basal and differentiating cells were recorded separately. the mitotic rate was measured by the stathmokinetic method and the cell cycle distributions were measured by flow cytometry of isolated basal cells at intervals during the labelling period. the mitotic rate of the [³H]TdR-injected animals did not deviate from control values during the first 5 d. Computer simulations of the data based on various mathematical models were made, and three main conclusions were obtained: (1) a large spread in transit times through the G₁ phase was found, together with a very narrow distribution in maturation time of differentiating cells; (2) about 20% of the differentiating cells were estimated to leave the basal cell layer directly after mitosis. This is consistent with results obtained from different sets of data; and (3) during continuous labelling more than 90% of the cells are labelled during each passage through the S phase.     

Influence of 3HTdR on the circadian rhythm—a model analysis for mouse epidermis

A mathematical model for the normal circadian rhythm in epidermis is formulated. It reproduces the experimental data for mice if the duration of either the G₁ or the S phase oscillates. As a second step, the model is generalized to account for the influence of ³HTdR on the circadian rhythm. A simultaneous interpretation of experimental curves for LI, PLM, the mitotic rate (MR) and the phase indices G₁I, SI, G₂I and MI measured by micro-spectrophotometry or flow cytometry, can be given by the following hypothesis. (a) Of the S phase cells (as measured by DNA content), only the most mature fraction is labelled. Some of these labelled cells die (or loose their label) within a few hours. The free label is then reutilized. (b) For about 12 hr the flux of unlabelled cells from G₁ into S phase is accelerated. These cells stay correspondingly longer in S so that their cell cycle time is scarcely affected. (c) The normal circadian triggering is disturbed for at least 36 hr after labelling. The implications of this hypothesis for double labelling experiments are discussed.     

CELL PROLIFERATION IN THE RAT KIDNEY INDUCED BY FOLIC ACID

The changes in proliferative activity of tubular epithelial cells of the rat kidney following a single injection of folic acid (250 mg/kg body weight) have been studied. Autoradiography with tritiated thymidine revealed a large increase in numbers of labelled cells, beginning at about 18 hr, in each of the three kidney zones examined. In the cortex the maximum increase in labelling index (16 times normal) was found at 36 hr whereas that of the outer medulla (34 times normal) occurred at 24 hr; there was no clearly defined peak in the inner medulla, values of up to 36 times normal being found between 24 and 96 hr. These changes were followed several hours later by similar changes in mitotic index in the corresponding zones. All the indices, except the mitotic index of the inner medulla, had returned to normal by 6 days. Comparison of the curves of labelling index and mitotic index in each zone indicated that the number of cells induced to synthesize DNA was approximately similar to the number of cells which subsequently underwent mitosis. A large increase was also found in the specific activity of DNA extracted from homogenates of whole kidneys from folic acid-injected rats, again using tritiated thymidine as label. The increase began at about 18 hr, reached a maximum of 16 times normal at 32 hr and returned to normal by 6 days. These changes were similar to those of labelling index in the cortical zone.     

Circadian rhythms in mouse epidermal basal cell proliferation. Variations in compartment size, flux and phase duration.

Several kinetic parameters of basal cell proliferation in hairless mouse epidermis were studied, and all parameters clearly showed circadian fluctuations during two successive 24 hr periods. Mitotic indices and the mitotic rate were studied in histological sections; the proportions of cells with S and G2 phase DNA content were measured by flow cytometry of isolated basal cells, and the [3H]TdR labelling indices and grain densities were determined by autoradiography in smears from basal cell suspensions. The influx and efflux of cells from each cell cycle phase were calculated from sinusoidal curves adapted to the cell kinetic findings and the phase durations were determined. A peak of cells in S phase was observed around midnight, and a cohort of partially synchronized cells passed from the S phase to the G2 phase and traversed the G2 phase and mitosis in the early morning. The fluctuations in the influx of cells into the S phase were small compared with the variations in efflux from the S phase and the flux through the subsequent cell cycle phases. The resulting delay in cell cycle traverse through S phase before midnight could well account for the accumulation of cells in S phase and, therefore, also the subsequent partial synchrony of cell cycle traverse through the G2 phase and mitosis. Circadian variations in the duration of the S phase, the G2 phase and mitosis were clearly demonstrated.