Analysis of Cell Flow and Cell Loss Following X-Irradiation Using Sequential Investigation of the Total Number of Cells In the Various Parts of the Cell Cycle

The cell flow and cell loss of an in vivo growing Ehrlich ascites tumour were calculated by sequential estimation of changes in the total number of cells in the cell cycle compartments. Normal growth was compared with the grossly disturbed cell flow evident after a 5 Gy X-irradiation. The doubling time of normal, exponentially growing cells was 24 hr. the generation time was 21 hr based on double-isotope labelling studies and the potential doubling time was 21 hr. Thus, the growth fraction was 1.0 and the cell loss rate about 0.5%/hr. Following irradiation, a transiently increased relative outflow rate from all cell cycle compartments was found at about 3 and 40 hr, and from S phase at 24 hr after irradiation. Minimum flow rates from all compartments were found up to 20 hr. Cell loss as calculated from the cell flow was compared with non-viable cells determined by Percoll density separation. Increase in cell loss as well as non-viable cells was observed at 24 hr after irradiation at the time of release of the irradiation-induced G₂ blockage. Up to 50 hr, about 70% of the initial total number of cells were lost. the experiments show the applicability and limitations of cell flow and cell loss calculations by sequential analysis of the total number of cells in the various parts of the cell cycle.     

Growth pattern of the human promyelocytic leukaemia cell line HL60

Abstract. In order to characterize the growth pattern of the human promyelocytic leukaemia cell line HL60, its kinetic parameters were studied. The doubling time was calculated from serial cell counts, the duration of the various cell cycle phases from the analysis of the labelled mitoses curve, and quiescent population from continuous labelling experiments. Proliferation in culture was exponential up to a saturation density of about 3.0 × 10⁶ cells/ml, with a doubling time of 34.0 hr. The cell cycle duration was 24.3 ± 4.1 hr (SD), and that of the cell cycle phases was: G₁, 3.8 ± 2.2 hr; S, 15.1 ± 3 hr; and G₂, 5.4 ± 1.2 hr. The growth fraction was 0.85, and cell loss was restricted to the quiescent cells. The HL60 cell line, with fully characterized kinetics, provides a useful tool for the in vitro study of substances which may affect human leukaemic myelopoietic proliferation.     

The cell cycle of spermatogonial colony forming stem cells in the CBA mouse after neutron irradiation

In the CBA mouse testis about 10% of the stem cell population is highly resistant to neutron irradiation (D0, 0.75 Gy). Following a dose of 1.50 Gy these cells rapidly increase their sensitivity towards a second neutron dose and progress fairly synchronously through their first post-irradiation cell cycle. From experiments in which neutron irradiation was combined with hydroxyurea it appeared that in this cycle the S-phase is less radiosensitive (D0, 0.43 Gy) than the other phases of the cell cycle (D0, 0.25 Gy). From experiments in which hydroxyurea was injected twice after irradiation the speed of inflow of cells in S and the duration of S and the cell cycle could be calculated. Between 32 and 36 hr after irradiation cells start to enter the S-phase at a speed of 30% of the population every 12 hr. At 60 hr 50% of the population has already passed the S-phase while 30% is still in S. The data point to a cell cycle time of about 36 hr, while the S-phase lasts 12 hr at the most.     

CYTOKINETIC STUDIES OF THE REGENERATIVE PHASE IN THE JB-1 ASCITES TUMOUR

The cell kinetics of recurrent growth of the murine JB-1 ascites tumour have been investigated 0 hr and 24 hr after aspiration of the main part of the tumour in the plateau phase of growth. The experimental data: growth curve, percentage of labelled mitoses curve and continuous labelling curves combined with cytophotometric determination of single-cell DNA content were analysed using two alternative mathematical models for the cell kinetics. Investigations 24 hr after aspiration showed that the doubling time had decreased to 70 hr as compared with 240 hr in the plateau tumour. This was due to a release of non-proliferating cells into the cell cycle, resulting in an increase in the growth fraction from 44% to 72%. The decrease in the doubling time was also due to a shortening of the mean cell cycle time from 41 to 20.5 hr. The analysis rendered it likely that the aspiration caused a shift in the mode of cell loss from an age-specific elimination of old non-cycling cells with post-mitotic DNA content in the plateau tumour to an elimination of younger cells immediately after mitosis. Investigations from 0 to 10 hr after aspiration verified the release of non-proliferating cells with both G₁ and G₂ DNA content into the cell cycle. The release was initiated from 3 to 6 hr after aspiration. 24 hr after aspiration the experimental data did not indicate any further transition.     

Properties of the H-4-II-E tumor cell system. II. In vitro characteristics of an experimental tumor cell line.

The growth and cell proliferation characteristics of the H-4-II-E cell line, giving rise to hepatoma H-4-II-E when inoculated into male ACI rats, were studied in vitro. Following seedling of 2 x 10(5) cells into culture dishes, exponential cell growth occurs in cultures fed both at 24 hr and 48 hr intervals with a population doubling time of 18-4 hr. Plateau phase growth conditions are established on day 7 and day 5 for cultures fed at 24 hr and 48 hr intervals respectively. Both the plateau phase cell density and the maintenance of plateau phase appear dependent on the frequency of feeding. For cultures fed daily, the transition from exponetial growth to plateau phase results from both a reduction in the number of proliferating cells (99% v. 35%) as well as an elongation of the cell cycle (17-7 hr v. 128-4 hr). The cell proliferation characteristics of the culture are further discussed in reference to both cell growth and feeding schedules of other cell lines.     

Alterations in the cell cycle of Drosophila imaginal disc cells precede metamorphosis

Flow cytometric analyses of imaginal disc and brain nuclei of Drosophila melanogaster have been made throughout the third larval instar. In wing, haltere, and leg discs the proportion of cells in the G₂M phase of the cell cycle (tetraploid cells) increases with larval age. In contrast, in the eye disc and in brain the proportion of tetraploid cells, already low at the outset of the instar, declines further. Measurement of growth rates for disc and brain tissue during the same developmental period was carried out by the cell counting procedure of Martin (1982). Our results are consistent with the conclusion that imaginal discs grow exponentially with an apparent doubling time of 5–10 hr from the resumption of cell division (in the first or second larval instar) until about 95 hr, when the apparent doubling time increases. Cell numbers increase until at least 5 hr after formation of white prepupae (122 hr), but during the preceding 10 hr the rate of increase is low. Thus, for wing and leg discs, but not for the eye disc and brain, the declining growth rate is associated with an increase in the proportions of tetraploid cells. In conjunction with cell counts and flow cytometry, fluorometric determination of disc DNA content at 112 hr indicated that the diploid DNA content of imaginal disc nuclei is 0.45 pg.     

Control of cell cycle entry and progression in mitogen-stimulated human B lymphocytes

Tonsillar B lymphocytes were stimulated to proliferate by the mitogenic combination of phorbol dibutyrate and ionomycin. Progression through the cell cycle was monitored by measurements of cellular DNA and RNA content using flow cytometry. Changes in surface expression of class II MHC antigens and CD20 antigen were also monitored as early parameters of B lymphocyte activation and cell cycle progression. The results showed that about 60% of the population synchronously entered and progressed through the cell cycle. The transition from the resting state, signaled by increased RNA content, occurred about 12 to 24 hr after stimulation; S phase entry occurred at about 36 hr. Small, variable populations of cells appeared to be unresponsive to the stimuli, either because they were “preactivated” before in vitro stimulation or were already dying. The kinetics of appearance and accumulation of several cell cycle regulated/regulatory proteins were followed by immunoblotting. The proliferating cell nuclear antigen (PCNA) cyclin A and p33^cdk2 proteins were either absent or present in very low amounts in resting cells and first became detectable in increased amount beginning at about 24 hr after stimulation; increased p34^cdc2 protein was not detected until about 36 hr. Increased cellular content and phosphorylation of the p110^Rb protein was already obvious by 24 hr after stimulation. The effects of several immunosuppressive agents were examined using purified B cells. Both cyclosporin A and an FK506 analogue were shown to inhibit proliferation of B lymphocytes, at the low doses also inhibitory to T cells. © 1995 Wiley-Liss, Inc.     

Establishment and characterization of human colonic and gastric cancer cell lines

Two human cancer cell lines, DAIT-6 from a colonic cancer and IT-25 from a gastric cancer, derived from xenografts in nude mice have been established in tissue culture and maintained for over two years. In tissue culture, DAIT-6 cells grew in a monolayered sheet with a population doubling time of about 45.0 hr, and floated or piled up to form small buds above the monolayered surface in relatively confluent cultures. Chromosomal counts ranged from 40 to 108 with a modal number of 59. The cells secreted CEA (1.7 ng/1 x 10(6) cells/24 hr) and CA19-9 (540.5 u/1 x 10(6) cells/24 hr) in spent medium. The IT-25 cells grew in a monolayered sheet with a population doubling time of about 57.8 hr in tissue culture. The IT-25 cells also secreted CEA (0.5 ng/1 x 10(6) cells/24 hr) and CA19-9 (120.0 u/1 x 10(6) cells/24 hr) in spent medium. The xenografts for DAIT-6 and IT-25 in nude mice were histopathologically classified as a moderately differentiated tubular adenocarcinoma and a well differentiated tubular adenocarcinoma, respectively.     

Effect of hypothermia on cell kinetics and response to hyperthermia and X rays

Hyperthermia is a potent radio enhancer. Studies using hypothermia in combination with irradiation have given confusing results due to lack of uniformity in experimental design. This report shows that hypothermia might have potential significance in the treatment of malignant cells with both thermo- and radiotherapy. Reuber H35 hepatoma cells, clone KRC-7 were used to study the effect of hypothermia on cell kinetics and subsequent response to hyperthermia and/or X rays. Cells were incubated at 8.5 degrees C or between 25 and 37 degrees C for 24 hr prior to hyperthermia or irradiation. Hypothermia caused sensitization to both hyperthermia and X rays. Maximum sensitization was observed between 25 and 30 degrees C and no sensitization was found at 8.5 degrees C. At 25 degrees C maximum sensitization was achieved in approximately 24 hr, cell proliferation was almost completely blocked, and cells gradually accumulated in the G2 phase of the cell cycle. In contrast to the effect of hypothermia on either hyperthermia or X rays alone, thermal radiosensitization was decreased in hypothermically pretreated cells (24 hr at 25 degrees C) compared to control cells (37 degrees C). The expression of thermotolerance and the rate of development at 37 degrees C after an initial heating at 42.5 degrees C were not influenced after preincubation at 25 degrees C for 24 hr. The expression of thermotolerance for heat or heat plus X rays during incubation at 41 degrees C occurred in a significantly smaller number of cells after 24 hr preincubation at 25 degrees C. The enhanced thermo- and radiosensitivity in hypothermically treated cells disappeared in approximately 6 hr after return to 37 degrees C.     

The Cell Cycle of Spermatogonial Colony Forming Stem Cells In the Cba Mouse After Neutron Irradiation

Abstract. In the CBA mouse testis about 10% of the stem cell population is highly resistant to neutron irradiation (D_o, 0.75 Gy). Following a dose of 1.50 Gy these cells rapidly increase their sensitivity towards a second neutron dose and progress fairly synchronously through their first post-irradiation cell cycle. From experiments in which neutron irradiation was combined with hydroxyurea it appeared that in this cycle the S-phase is less radiosensitive (D_o, 0.43 Gy) than the other phases of the cell cycle (D_o, 0.25 Gy). From experiments in which hydroxyurea was injected twice after irradiation the speed of inflow of cells in S and the duration of S and the cell cycle could be calculated. Between 32 and 36 hr after irradiation cells start to enter the S-phase at a speed of 30% of the population every 12 hr. At 60 hr 50% of the population has already passed the S-phase while 30% is still in S. the data point to a cell cycle time of about 36 hr, while the S-phase lasts 12 hr at the most.     

Theileria parva: cell culture analysis of clones of macroschizont-infected bovine lymphoblastoid cells

Three clones (H7, D7, and C5) were established from single cells of a bovine lymphoblastoid cell line (IR.TPM.1) infected with macroschizonts of the protozoan parasite Theileria parva. The cloning efficiency using feeder layers was 0.3–0.4. The mean parasite size (the number of parasite nuclei per cell) was different in each clone and was correlated to the growth rate. The fast growing clone, C5 (population doubling time 24 hr), contained smaller (mean parasite nuclear number, 12) parasites than a slow growing clone, D7 (population doubling time, 73 hr; mean number of parasite nuclei per cell, 35.3). The third clone, H7, had an intermediate growth rate (population doubling time, 49 hr) and parasite size (mean nuclei number, 18.1). There was variation in the incidence of microschizonts among the clones but microschizont-free clones were not isolated. When the clones were subjected to 4.3 × 10^?7M aminopterin, 20–25% of the cell population of clones H7 and C5 and the uncloned parent line lost their parasites in 4 days, while it took 7 days to reach a similar result (31% parasite-free cells) in clone D7. We were unable to isolate parasite-free clones from cells treated with aminopterin. Hydroxyurea (4 × 10^?4M) inhibited the growth of clone C5, but the macroschizonts continued to proliferate, and the incidence of cells with microschizonts increased. The size profile analysis showed that most of the aminopterin-treated cells were 9.0 μm, the hydroxyurea-treated cells 14.7 μm, and the untreated cells 10.8 μm in diameter.     

Bromodeoxyuridine labeling and flow cytometric identification of replicating Saccharomyces cerevisiae cells: lengths of cell cycle phases and population variability at specific cell cycle positions.

An immunofluorescent staining procedure has been developed to identify, with flow cytometry, replicating cells of Saccharomyces cerevisiae after incorporation of bromodeoxyuridine (BrdUrd) into the DNA. Incorporation of BrdUrd is made possible by using yeast strains with a cloned thymidine kinase gene from the herpes simplex virus. An exposure time of 4 min to BrdUrd results in detectable labeling of the DNA. The BrdUrd/DNA double staining procedure has been optimized and the flow cytometry measurements yield histograms comparable to data typically obtained for mammalian cells. On the basis of the accurate assessment of cell fractions in individual cell cycle phases of the asynchronously growing cell population, the average duration of the cell cycle phases has been evaluated. For a population doubling time of 100 min it was found that cells spend in average 41 min in the replicating phase and 24 min in the G2+M cell cycle period. Assuming that mother cells immediately reenter the S phase after cell division, daughter cells spend 65 min in the G1 cell cycle phase. Together with the single cell fluorescence parameters, the forward-angle light scattering intensity (FALS) has been determined as an indicator of cell size. Comparing different temporal positions within the cell cycle, the determined FALS distributions show the lowest variability at the beginning of the S phase. The developed procedure in combination with multiparameter flow cytometry should be useful for studying the kinetics and regulation of the budding yeast cell cycle.     

Kinetics of Micronucleus Expression In Synchronized Irradiated Chinese Hamster Ovary Cells

The kinetics of expression of radiation-induced micronuclei (MN) in synchronized Chinese hamster cells (CHO) was examined. the purpose of the study was to determine if the cell cycle distribution of a population significantly influences the levels of radiation induced MN, thereby obscuring the exact quantification of the radiation effect. Cells were synchronized by centrifugal elutriation, irradiated, and then different phases of the cell cycle were examined for: cell cycle progression, division probability, and temporal expression of MN. the results demonstrate that the time interval for maximal MN expression is long enough that the position of cells in the cell cycle and radiation induced division delays do not prevent the majority of cells from completing their first post-irradiation mitosis, therefore, expressing MN. By following the progression of synchronized cell populations by flow cytometry and also examining the time of division of individual cells for 24 hr after irradiation, we observed that the maximum number of cells from all phases of the cell cycle are in their first post-irradiation interphase at that time, thus explaining the MN results.     

Kinetics of micronucleus expression in synchronized irradiated Chinese hamster ovary cells

The kinetics of expression of radiation-induced micronuclei (MN) in synchronized Chinese hamster cells (CHO) was examined. The purpose of the study was to determine if the cell cycle distribution of a population significantly influences the levels of radiation induced MN, thereby obscuring the exact quantification of the radiation effect. Cells were synchronized by centrifugal elutriation, irradiated, and then different phases of the cell cycle were examined for: cell cycle progression, division probability, and temporal expression of MN. The results demonstrate that the time interval for maximal MN expression is long enough that the position of cells in the cell cycle and radiation induced division delays do not prevent the majority of cells from completing their first post-irradiation mitosis, therefore, expressing MN. By following the progression of synchronized cell populations by flow cytometry and also examining the time of division of individual cells for 24 hr after irradiation, we observed that the maximum number of cells from all phases of the cell cycle are in their first post-irradiation interphase at that time, thus explaining the MN results.     

CHANGES IN CELL PROLIFERATION KINETICS OCCURRING DURING THE LIFE HISTORY OF MONOLAYER CULTURES OF A MOUSE TUMOUR CELL LINE

Following inoculation of monolayer cultures of EMT6 mouse tumour cells at 10⁵ cells, a short lag is followed by 3 days of exponential growth with a population doubling time of 12 hr. A plateau cell number is reached between days 4 and 5 and is maintained for at least 8 days. During exponential growth, the pulse ³H-TdR labelling index is 55–60%, all cells are in cycle, and the median cycle time is 11–12 hr. For the first 3 days of plateau phase, the labelling index is about 25 % and there is considerable cell loss. The cell cycle is 32–40 hr, and S-phase is very long. Later in plateau phase, the labelling index falls to <2 % and there is little cell loss. The changes in kinetics occurring in EMT6 cultures are discussed with reference to reported changes occurring in other cell lines.     

Evidence for discrete cell kinetic subpopulations in mouse epidermis based on mathematical analysis

Abstract. Continuous (repeated) labelling studies in mouse epidermis indicate that nearly all cells are labelled after about 100 hr. Percentage labelled mitoses studies ([³H]TdR at 15.00 and 03.00 hours) have a first peak that does not reach 100% and has a half-width of about 10 hr. Small second and third peaks can be detected at about 90 and 180 hr, respectively. The changes with time in the number of labelled cells show a difference dependent on the time of day of [³H]TdR administration. Both curves show an early doubling in labelled cells which then decline, forming a peak of labelled cells. A second peak occurs at about 120 hr. This is followed by a progressive decline with no further peaks until values of about 1% labelling are obtained at 340 hr.
These experiments have been investigated mathematically. A computer programme has been devized that permits all three types of experiments to be analysed simultaneously. More importantly, it can analyse situations with a heterogeneity in cell cycle parameters in all proliferative subpopulations.
Various models for epidermal cell replacement have been considered. The data as a whole can best be explained if the basal layer contains at least two distinct subpopulations of cells and an exponentially decaying post-mitotic population with a half-life of about 30 hr. The proliferative sub-populations must be characterized by near integer differences in the length of cycle, the precursor (stem) compartment having the longer cycle. An inverse relationship is required for the length of S, i.e. the shortest time for the stem cells.
A full range of cell kinetic parameters can be calculated and are tabulated for the most appropriate model system which is one involving three transit proliferating subpopulations.     

Synchronization of the human promyelocytic cell line HL 60 by thymidine

Cultures of the promyelocytic cell line HL 60 were synchronized with thymidine. A concentration of 0.05 mM thymidine and an exposure time of 24 hr was found optimal for blocking about 90% of the cells in S phase. Following release from the thymidine block the cell cultures were followed intermittently over 40 hr for fluctuation in cell numbers, labelling with radioactive thymidine and nuclear DNA distributions. Mathematical evaluation of the results revealed a cycling time of 18.6 hr and a duration of specific cell phases of 8.6 hr, 7.1 hr and 2.9 hr for G1, S and G2 + M, respectively. The doubling time was 26 hr and the growth fraction was estimated as 1.     

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 10(4)--5 X 10(5) 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 hrs. Transit times for each stage were: TG1 = 10.6 hr, TS = 9.9 hr, TG2 = 9.9 hr, and TM = 0.7 hr. Repeated experiments using continuous labeling with 3H-TdR demonstrated a TG2 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 TG1 = 14.1 hr, TS = 9.9 hr, TG2 = 6.3 hr, and TM = 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.     

The Growth of the Emt6 Tumour In the Lungs of Balb C Mice Following Intravenous Inoculation of Tumour Cells From Culture

The growth of the EMT6 tumour in the lungs of Balb C mice has been studied following intravenous inoculation of different numbers of tumour cells taken from culture. At various times after injection of cells into mice, cell suspensions have been prepared from pairs of lungs and the number of in vitro colony forming cells assayed by plating into petri dishes. Following intravenous injection of 10⁵ cells, the time required for doubling of the number of clonogenic tumour cells appearing in the cell suspension is around 17 hr until such time that the total tumour cell population per set of lungs reaches 10⁸ cells (at 10–12 days). This doubling time has to be corrected for changes in ability to extract cells from the lungs into the cell suspension at various times and also for possible changes in plating efficiency in vitro. When these correction factors are applied, the most likely value for the doubling time of clonogenic tumour cells in the lungs is in the range 20–24 hr. This is a similar figure to that previously deduced for the EMT6 flank tumour during its microscopic period of growth. After reaching a total size of 10⁸ tumour cells, the time for doubling of the number of clonogenic tumour cells in the lung increases. During the later stages of tumour growth a good correlation is seen between total lung tumour weight and the number of clonogenic cells present. For the final 3–4 days of the initial period of rapid tumour growth, it is possible to carry out a haemocytometer count of tumour cells in the lung suspension and hence surviving fraction experiments may be carried out after various forms of treatment. In this way the response to treatment of microscopic tumour foci may be determined.