ANALYSIS OF THE GROWTH KINETICS OF A HUMAN LYMPHOMA CELL LINE

The growth kinetics of an established human lymphoma cell line were analyzed by a variety of techniques utilizing various cell inocula (5 x 10⁴ - 5 x 10⁵ cells) dispensed into 60 mm diameter dishes. Techniques included pulse-labeled mitosis (PLM), continuous labeling with ³H-TdR, time-lapse photography (TLP), cell counts by electronic particle counter, and DNA histography obtained by pulse cytophotometry (PCP). There were no significant differences among values determined for any kinetic parameters as a function of cell concentration. the average doubling time of exponentially growing cells, regardless of cell inoculum, was 44.1 hr. the generation time determined by PLM was 31.1 hr with a SD of 4.7 hr. Transit times for each stage were: T_G1= 10.6 hr, T_s= 9.9 hr, T_G2= 9.9 hr, and T_m= 0.7 hr. Repeated experiments using continuous labeling with ³H-TdR demonstrated a T_G2 of 6.3 hr. the longer value determined by PLM is possibly due to the technical manipulations of this procedure which may delay pulse-labeled cells from resuming cell cycle transit. Hence, values for cell cycle stages were recalculated to give T_G1= 14.1 hr, T_s= 9.9 hr, T_G2 = 6.3 hr, and T_m= 0.7 hr. These results were used to compute the size of each cell cycle stage compartment pool and corresponded very closely to values defined directly by PCP. TLP analysis considered only cells that produced colonies of at least thirty-two cells. Generation times ranged from 8 to 89 hr and showed a positive skewness. the average value measured for 330 divisions was 34.5 hr with a SD of 13.2 hr. Thus, the variance predicted by curve fitting of the PLM data did not correlate with that defined by time-lapse photography nor did it encompass the range in generation times observed directly by TLP. There was a positive correlation between sister-sister cell generation times (+0.66) but no relation was noted for mother-daughter values.     

Cell cycle kinetics of uninfected and feline leukemia virus-infected canine lymphoma cell lines: effects of methotrexate treatment

The cell cycle kinetics of uninfected and feline leukemia virus-infected canine lymphoma cell lines were determined by autoradiography (PLM method) as follows: DT-5: generation time (TC), 15.2 h; pre-synthetic gap phase (TG1), 3.2 h; DNA-synthetic phase (TS), 8.2 h; post-synthetic gap ph se (TG2), 3.3 h; visible mitotic phase (TM), 0.5 h. 11028: TC, 13.6 h; TG1, 1.9 h; TS, 7.7 h; TG2, 3.4 h; TM, 0.6 h. 11028+FeLV (11028 productively infected with feline leukemia virus): TC, 11.2 h; TG1, 0.2 h; TS, 8.3 h; TG2, 2.1 h; TM, 0.6 h. Exposure of the lymphoma cell lines to methotrexate (MTX) in vitro produces dose-related increases in cellular volume, associated with reductions in cellular proliferation. The relative sensitivities of these cell lines to MTX, measured by the ID50 MTX concentrations for DT-5, 11028, and 11028+FeLV are 118 nM, 122 nM, and 28 nM respectively. The cell kinetic effects of the ID50 MTX concentrations added to cultures of lymphoma cells pulse-labeled with tritiated thymidine are an approximately 2-h prolongation of TC, attributable to a lengthening of TS, with other cell cycle phases not significantly altered. These cell lines are highly tumorigenic when transplanted into the cheek pouches of immunosuppressed hamsters, with inocula of 10(4) cells producing rapidly growing, well vascularized tumors.     

Cell synchrony techniques. II. Analysis of cell progression data

CHO cells which have been sorted by mitotic detachment, centrifugal elutriation and fluorescence activated cell sorting have been followed for up to 14 hr by flow cytometry to examine their progression characteristics. Mathematical modelling techniques were used to provide quantitative estimates of the cell-cycle parameters. Mitotic detachment gives an 11.2-hr cycle time with mean transit times TG1, TS and TG2M equal to 3.2, 5.6 and 2.4 respectively. Cells prepared by central elutriation in an early G1 state have a 14-hr cycle time with TG1, TS and TG2M of 5.7, 6.0 and 2.3 hr. Populations prepared by centrifugal elutriation enriched in early S and late S and G2M have transit times of 2.7, 5.9 and 1.6 hr and 4.9, 6.7 and 2.1 hr with cycle times of 11.2 and 13.2 hr respectively. Cell sorting for a G1 population gives transit times of 9.8, 8.0 and 3.6 for an overall 21.4-hr cycle time.     

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.     

Studies on the population kinetics of the Walker carcinoma by autoradiography and pulse cytophotometry.

The proliferation parameters of the Walker carcinoma were estimated from both in vivo and in vitro measurements. tthe transplantable Walker carcinoma 256 was grown in male inbred BD1 rats. During exponential growth, 5--6 days after transplantation, a PLM curve was performed, yielding estimates of TC approximately equal to 18-0 hr, TS approximately equal to 6-4 hr, TG2+M approximately equal to 4-1 hr. With the double labelling technique in vitro under 2-2 atm oxygen we obtained: TC approximately equal to 18-2 hr, TS approximately equal to 8-2 hr, TG2+M approximately equal to 2-0 hr. From pulse cytophotometry DNA content histograms the fractions of cells in the cell cycle phases were calculated using a computer program: fG1 approximately equal to (47-6 +/- 1-1)%, fS approximately equal to (34-1 +/- 1-0)%, fG2+M approximately equal to (18-3 +/- 1-5)%. These fractions remained constant between the fifth and the twelfth day after transplantation. At that time the tumour growth had already slowed down appreciably. The growth fraction determined by repetitive labelling was 0.96 on the fifth and 0-93 on the seventh and eleventh day. The cell loss factor was phi approximately equal to 17% during exponential tumor growth and increased to about 100% between the tenth and twelfth day. The agreement of the cell kinetic data determined by autoradiography from solid tumours in vivo (PLM, continuous labelling) and autoradiography as well as pulse cytophotometry from in vitro experiments (excised material) was satisfactory.     

The differentiation of T-lymphocytes. III. The behaviour of subpopulations of mouse thymus cells in short-term cell culture.

Seven human cultured lymphoblastoid cell lines (CLL) were divided into two major groups based on studies of their cell cycle characteristics and surface Ig. CLL I (lines CL, MW, HH and TM) had generation times ranging from 25–40 hr, S phase times of 10–12 hr, G₂ + M times of 6–8 hr, and demonstrated sharp differences between the percentage of SIg(+) cells in different phases of the cell cycle. Line TM was particularly discordant with the highest percentage of SIg(+) cells in G₂ + M. CLL II (lines PS, JR and HT) demonstrated generation times ranging from 18–21 hr, S phase times of 7–10 hr and G₂ + M phase times of 2 hr. In this second group, two of the three CLLs had no differences between cells taken from different points of the cell cycle. DNA synthesis and cell density could not be correlated with either of the above major parameters, i.e. cell cycle times or SIg expression. The results suggest that human CLLs fall into subgroups in which specific patterns of cellular and immune functions may predominate.     

Quasi-exponential generation time distributions from a limit cycle oscillator

In spite of the apparently random behaviour and the often exponential distribution of generation times expressed in cell populations, there is evidence for rather precise timekeeping in the cell cycle. In experiments using time-lapse video-tape microscopy, we have noted that cell generation times are often not distributed smoothly but in many cases seem to cluster at roughly 4 hr intervals. Phase shift responses following application of heat shock, ionizing radiation or serum pulses in each case show a pattern which is repeated twice in cells with an 8-9 hr modal generation time. We describe here a cell cycle model with an independent cellular clock controlling cell cycle events which accounts for the phase response data, while also reconciling the stochastic and periodic behaviour characteristic of animal cells.     

Quasi-Exponential Generation Time Distributions From A Limit Cycle Oscillator

In spite of the apparently random behaviour and the often exponential distribution of generation times expressed in cell populations, there is evidence for rather precise timekeeping in the cell cycle. In experiments using time-lapse video-tape microscopy, we have noted that cell generation times are often not distributed smoothly but in many cases seem to cluster at roughly 4 hr intervals. Phase shift responses following application of heat shock, ionizing radiation or serum pulses in each case show a pattern which is repeated twice in cells with an 8–9 hr modal generation time. We describe here a cell cycle model with an independent cellular clock controlling cell cycle events which accounts for the phase response data, while also reconciling the stochastic and periodic behaviour characteristic of animal cells.     

Non-circadian periodicity in the duration of the cell cycle and the G1 phase in the hindlimb epidermis of the anuran tadpole, Rana pipiens

Using the percentage labeled mitoses method, seven cell cycle determinations were initiated at 6-hr intervals over a 36-hr span in order to see if the cell cycle in the tadpole hindlimb epidermis varied with time or showed rhythmicity. There was a pattern of two long cell cycles followed by a shorter one. Total cell cycle length (Tc) and the length of the G1 phase plus one-half of the mitotic time (TG1 + 1/2M) fluctuated the most, although only TG1 + 1/2M varied significantly with the Chi-square test. The proportion of TC spent in each phase was also calculated. Only TG1 + 1/2M/TC had statistically significant fluctuations with time. Rhythmicity was analyzed by a computer program using the method of least squares for cosine curve fitting. Statistically significant ultradian rhythms of 18.4 hr in TC, 18.5 hr in TG1 + 1/2M and 18.6 hr in TG1 + 1/2M/TC and the length of the DNA synthetic phase/total cell cycle length (TS/TC) were found. Circadian rhythmicity was not observed. The acrophases of the ultradian rhythms of TC and TG1 + 1/2M coincided, suggesting that the rhythm of TC was due mainly to variation in TG1 + 1/2M. In the absence of significant variation in TS, the longest phase of the cell cycle, whenever G1 + 1/2M was short, TS/TC increased, so that the 18.6 hr rhythm in TS/TC was also a result of the periodicity in TG1 + 1/2M.     

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.     

Cell cycle distributions, growth characteristics, and variation in prolactin and growth hormone production in cultured rat pituitary cells.

Clonal strains of rat pituitary tumour cells (GH3 cells) spontaneously produce and secrete prolactin and growth hormone. Chromosome analysis and DNA ploidy measurements revealed that the GH3 cells in the present study were triploid and had a decreased chromosome number compared to the parent strain. Monolayer cultures of these cells grow exponentially for 6-7 days with a mean doubling time of 54 h. Cell cycle distributions and phase durations were determined by micro-flow fluorometric measurements of cellular DNA content combined with computer calculations. During exponential growth the cell cycle distribution did not change (65.4% cells with a G1 phase DNA content, 24.9% with an S phase DNA content, and 9.7% with a (G2 + M) phase DNA content). Counting of mitoses gave 1.4% cells in M phase. The 3H-Tdr labeling indices were determined by autoradiography, and the results were in good agreement with the number of cells in S phase as calculated by micro-flow fluorometry. The phase durations were: Ts=15.9 h, TG2=6.2 h, TM=1.1 h, and TG1=30.9 h. TS and TM calculated from 3H-Tdr labeled and Colcemid treated cultures gave corresponding results. In plateau phase cultures the number of cells with a G1 DNA content increased to 80% and the number of cells with an S phase DNA content decreased to between 5% and 10%. The specific production of prolactin and growth hormone determined by radioimmunoassay showed two and four-fold increases respectively, during exponential growth. The hormone values decreased to initial or subinitial values (day 2 values) when approaching plateau phase. We conclude: that changes in the cell cycle distribution of the cell population cannot be responsible for the spontaneous alterations in hormone production during growth and that most of the hormone-producing cells must be in the G1 phase.     

Distribution of interdivisional times in proliferating and differentiating Friend murine erythroleukaemia cells

The interdivisional times of Friend murine erythroleukaemia cells which are growing continuously, or during terminal erythroid differentiation after exposure to dimethyl sulphoxide (DMSO), were determined by time lapse video photography. The median interdivisional times were found to increase from 11.75 hr before exposure to DMSO, to 24.0 hr at 72 hr after exposure. This increase in median interdivisional time was accompanied by an increase in heterogeneity of interdivisional times (%CV = 8.5----40.8), by an increase in the similarity of sister interdivisional times (ryy = 0.622----0.925), and by a decrease in the fraction of cells observed to divide (F = 1.0----0.807). Cells exposed to DMSO for 72 hr can be induced to divide at least once with nearly normal interdivisional times, if they are resuspended at a tenfold higher cell concentration. Computer simulations of cell cycle regulation, based on the opposing reactions model of Murphy, generate interdivisional time distributions which resemble the experimental data better than the single transition probability model of Smith and Martin.     

SENSITIVITY OF EARLY EMBRYONIC THYMIC LYMPHOID DEVELOPMENT TO 3H-THYMIDINE OF HIGH SPECIFIC ACTIVITY

The pulse technique, using high specific activity ³H-TdR to selectively kill cells in cell cycle, was applied to the thymic anlagen of chick embryos. With optimal specific and total ³H-TdR activities and pulse times of 2–4 hr the subsequent lymphoid development in organ culture of the thymic anlagen of 10-day-old chick embryos could be almost completely inhibited. The most important effect of the ³H-TdR was on the lymphoid precursor cells of the anlagen. The thymic epithelium appeared more resistant to ³H-TdR and allowed a lymphoid development of pulsed anlagen grafted to the chorioallantoic membrane of chick embryos when new lymphoid precursor cells were provided. The lymphoid precursor cells of the thymic anlagen of 10-day-old chick embryos therefore appeared to be in cell cycle with short generation time. The thymic anlagen of 8-, 9- and 10-day-old but not 7-day-old embryos showed a lymphoid development in organ culture. They did not differ with respect to the sensitivity to hot pulses of ³H-TdR. Thus no evidence of a lag in the onset of lymphoid precursor cell proliferation during the development of the early embryonic chick thymus was noted.     

In vitro response of lymphocytes to phytohemagglutinin (PHA) as studied with antiserum to PHA : II. Cell cycle analyses

The cell cycle and phase times of human lymphocytes responding to PHA have been analysed with the percent labelled metaphases (PLM) technique. The range of generation times (13–18 h) and DNA synthesis times (6.5–10.5 h) reported here compare well with previous measurements in the literature. Cycle analyses of the early responding cells of the initial response, selected with partial anti-PHA serum inhibition, and of restimulated cells yield relatively well-defined PLM curves. The short cycle times measured from these curves may reflect the early cycles after stimulation or a subpopulation of responding cells. Analyses at two times during both the initial and restimulation responses suggest that cycles lengthen with time after stimulation. The poor PLM curves of the initial response and the restimulation response of cells released from anti-PHA inhibition indicate considerable intercellular variation in cycle times. Cells in the initial long G 1 phase contribute to this variation. PHA dose does not appear to affect the cycle time.     

Distribution of Interdivisional Times In Proliferating and Differentiating Friend Murine Erythroleukaemia Cells

Abstract. The interdivisional times of Friend murine erythroleukaemia cells which are growing continuously, or during terminal erythroid differentiation after exposure to dimethyl sulphoxide (DMSO), were determined by time lapse video photography. the median interdivisional times were found to increase from 11.75 hr before exposure to DMSO, to 24.0 hr at 72 hr after exposure. This increase in median interdivisional time was accompanied by an increase in heterogeneity of interdivisional times (% CV = 8-5 → 40.8), by an increase in the similarity of sister interdivisional times (r_yy= 0.622 → 0.925), and by a decrease in the fraction of cells observed to divide ( F = 1. 0 → 0.807). Cells exposed to DMSO for 72 hr can be induced to divide at least once with nearly normal interdivisional times, if they are resuspended at a tenfold higher cell concentration. Computer simulations of cell cycle regulation, based on the opposing reactions model of Murphy, generate interdivisional time distributions which resemble the experimental data better than the single transition probability model of Smith and Martin.     

On the measurement of cytokinetics by continuous labeling with bromodeoxyuridine with applications to chick wing buds.

The cytokinetic properties, specifically the phase-transit times, TG1, TS, and TG2+M, of chick wing bud cells were estimated using data obtained from continuous labeling of stage 20 embryos with bromodeoxyuridine (BrdUrd). The presence of BrdUrd was detected with monoclonal antibodies, and the amount of DNA in the cells was determined with propidium iodide. The fraction of cells in each cell cycle phase, the fraction of labeled cells, and the relative movement, a measure of the mean DNA content, of all labeled cells were evaluated using bivariate flow cytometry at successive times following introduction of the label. Equations are presented to describe the fraction of unlabeled cells in G2 + M, which gives a direct estimate of TG2+M; the fraction of all labeled cells, which can then be used to estimate TG1; and, finally, the relative movement, which provides an estimate of TS. Thus, the data measured in these experiments together provide estimates of the progression through the cell cycle of limb mesoderm cells.     

Intestinal cell proliferation. I. A comprehensive model of steady-state proliferation in the crypt

Cell replacement in the crypt of the murine small intestine has been studied and modelled mathematically under steady-state conditions. A great deal of information is available for this system, e.g. cell cycle times, S phase durations, the rate of daily cell production, the Paneth cell distribution etc. The purpose of the present work was to consider simultaneously as much of these data as possible and to formulate a model based upon the behaviour of individual cells which adequately accounted for them. A simple mathematical representation of the crypt has been developed. This consists of sixteen stem cells per crypt (TC = 16 hr, TS = 9 hr), and four subsequent transit cell divisions (TC = 11 to 12 hr, TS = 8 hr) before maturation. Experimental data considered to test the modelling were LI and data on the number of vertical runs of similarly labelled cells. All data were obtained from the ileum after 25 microCi [3H]TdR given at 09:00 hours. A number of alternative assumptions have been considered and either accepted or rejected. Two alternative model concepts of cell displacement explain the data equally well. One is dependent upon strong local cell generation age determinance while the other could accommodate any weak local cell displacement process in conjunction with an environmental cut-off determinant at the middle of the crypt. Both models provide new interpretations of the data, e.g. certain rates of lateral cell exchange between neighbouring columns (250 to 350 per crypt per day out of a total of 420 cell divisions per day) can be concluded from run data, while LI data provide information about the mechanisms involved in maintaining a position-related age order in the crypt.     

Regulation of thymidylate synthase enzyme synthesis in 5-fluorodeoxyuridine-resistant mouse fibroblasts during the transition from the resting to growing state

Thymidylate synthase (TS) activity is very low in resting mouse 3T6 fibroblasts but increases sharply in growth-stimulated cells at about the same time the cells enter S phase. To study the mechanism responsible for the increase in TS level, we isolated a 5-fluorodeoxyuridine (5-FdUrd)-resistant cell line (LU3-7) that overproduces TS and its mRNA about 50-100-fold. In this paper we show that the LU3-7 cells were able to rest in the G0 state of the cell cycle when maintained in medium containing 0.5% serum. When the serum concentration was increased to 10%, the resting cells reentered the cell cycle and began DNA replication about 12 hr later. TS activity remained at the resting level until DNA replication began, then increased at later times. The increase was not affected when the cells were stimulated in the presence of DNA synthesis inhibitors. The rate of synthesis of TS (as determined in a pulse-labeling experiment) remained at the resting level for the first 10 hr following stimulation, then increased 8-9-fold by 25 hr following serum stimulation. The half-life of TS in growing LU3-7 cells was measured in a pulse-chase experiment and found to be greater than 24 hr. Therefore the increase in TS activity was primarily due to an increase in the rate of synthesis of the enzyme. Since TS gene expression appears to be regulated in a similar manner in LU3-7 cells and in the parental 3T6 cells, the LU3-7 cells should be a good model system for detailed analysis of the mechanism for regulating TS gene expression in mammalian cells.     

EVIDENCE OF RAPID AND SLOW PROGRESSION OF CELLS THROUGH G2 PHASE IN MOUSE EPIDERMIS: A COMPARISON BETWEEN PHASE DURATIONS MEASURED BY DIFFERENT METHODS

Percentage labelled mitosis (PLM) measurements were initiated at four different times during a 24-hr period and continued for 24 hr in hairless mouse epidermis. Estimates of G₂ and S phase durations (mean T_G2 and mean T_S) were calculated. A significant number of labelled mitoses (10–20%) was seen after 30 min in all four PLM measurements and the estimated mean T_G2 varied from 1.4 to 2.5 hr and was in agreement with values from PLM measurements in other epithelial tissues. These mean T_G2 values were much shorter than expected from [³H]TdR double labelling experiments and from a multiparameter cell kinetic study in hairless mouse epidermis and did not reflect the circadian variations seen in these studies. the differences in estimates of phase durations can be explained by postulating two G₂ cell populations; one with a rapid and another with a slow rate of cell cycle progression. the cells with the higher rate are mainly registered by the PLM method, whereas those with the lower rate largely escape detection by this method. T_G2 estimates from PLM measurements in mouse epidermis therefore do not reflect the phase duration of the entire G₂ population. It is also concluded that circadian variations in T_S can not be accurately registered by the PLM method.     

CELL CYCLE TIME DETERMINATIONS BASED ON LIQUID SCINTILLATION COUNTING OF 3H-TdR LABELED MITOTIC CELLS

Following a 10 min pulse labeling with ³H-TdR, flasks of asynchronous monolayer cultures of Chinese hamster ovary cells were subjected to mitotic selection at 2 hr intervals. The mitotic index of the selected populations was always greater than 90%. Counts per min per cell obtained by liquid scintillation counting were plotted versus time after the pulse label. Comparisons were made between cycle times obtained by the mitotic-scintillation counting method and by the standard per cent labeled mitosis technique. The resulting curves were used for calculations of the cell cycle times and the lengths of G₁, S, G₂ and M phases of the cell cycle. There was less than 2% difference in the cell cycle times obtained using the scintillation method as compared to times calculated from autoradiographic data obtained from individual petri dishes. The mitotic-scintillation counting technique is simple, accurate and rapid and allows the calculation of the cell kinetics parameters within 1 hr of the end of the experiment.