A Novel Approach to the Study of Kinetically Changing Cell Populations

A method is described for estimating changes in cell cycle times during periods of rapid change in proliferation rate. This method, which depends upon the interpretation of pre- and post-velocity sedimentation fractionation continuous thymidine labelling patterns, exploits the relationship between sedimentation rate and cell cycle location. By this means, cycle times can be estimated under conditions that are difficult (if not impossible) to analyse by FLM methods.     

Characterization of a CV-1 cell cycle. V. An assessment of velocity sedimentation for cell separation and synchrony.

Velocity sedimentation at unit gravity has been used to enrich populations of logarithmically growing cells in different cell cycle phases. In order to evaluate the degree of synchrony obtained by this method of cell separation, synchronous populations of CV-1 cells, initially obtained by the selective detachment of mitotic cells from roller cultures, were separated by velocity sedimentation. It was found that although the mean cell volume increased linearly, the cells remained heterogeneous with respect to size during all phases of the cell cycle. Since the velocity sedimentation technique depends upon discrimination of cell size, the size heterogeneity of cells throughout the cycle limits the degree of synchrony which can be obtained by this method.     

ANTIBODY-PRODUCING CELLS: ANALYSIS AND PURIFICATION BY VELOCITY SEDIMENTATION

Velocity sedimentation cell separation is a simple and reproducible method for obtaining highly enriched populations of viable antibody-producing cells. Using suspensions of spleen cells prepared from mice immunized with sheep erythrocytes, fractions containing up to 2% 19S-PFC and 25% 7S-PFC can be obtained. Granulocytes constitute almost all of the remaining cells in these fractions. The sedimentation profile of 7S-PFC is very broad in comparison with that of cell populations known to be homogeneous in size (e.g. mouse erythrocytes). Analysis of the profile of 7S-PFC at different times after immunization suggests that the heterogeneity arises largely from the doubling in cell volume as a cell moves from one mitosis to the next. Early in the immune response, when the majority of the PFC are proliferating, the variation in sedimentation velocities is consistent with such a two-fold variation in cell volume. Late in the response, when most PFC have stopped proliferating, the sedimentation profile is more homogeneous. This analysis suggests that the fractionation procedure is sensitive enough to separate PFC according to their position in the cell cycle. Sedimentation velocities were also measured for several other classes of cells found in spleen. Comparison of these values shows that sedimentation velocity is a useful parameter for characterizing different types of cells.     

A non-invasive method for the routine-estimation of fresh weight of cells grown in batch suspension cultures

A simple apparatus was designed to allow sedimentation of plant cells grown in batch suspensions in Erlenmeyer flasks. After sedimentation the height of the cell mass along the glass wall was measured with a ruler fixed in the apparatus. The cell volume after sedimentation, calculated from this height, appeared highly correlated with the fresh weight of cells. This result was found with eight cell lines in two Laboratories. The method proved to be very suitable to allow routinely measurement of FW without the destruction of cells, from many samples, in a short time, during each phase of the growth cycle.Abbreviations CVS cell volume after sedimentation - FW fresh weight of cells     

Cell volume increase in Escherichia coli after shifts to richer media.

Synchronous cultures of Escherichia coli 15-THU and WP2s, which were selected by velocity sedimentation from exponential-phase cultures growing in an acetate-minimal salts medium, were shifted to richer media at various times during the cell cycle by the addition of glucose or nutrient broth. Cell numbers and mean cell volumes were measured electronically. The duration of the division cycle of the shifted generation was not altered significantly by the addition of either nutrient. Growth rates, measured as rates of cell volume increase, were constant throughout the cycle in unshifted acetate control cultures. When glucose was added, growth rates also remained unchanged during the remainder of the cell cycle and then increased abruptly at or after cell division. When nutrient broth was added, growth rates remained unchanged from periods of 0.2 to 0.4 generations and then increased abruptly to their final values. In all cases, the cell volume increase was linear both before and after the growth rate transition. The strongest support for a linear cell volume increase during the cell cycle of E. coli in slowly growing acetate cultures, however, was obtained in unshifted cultures, in complete agreement with earlier observations of cell volumes at much more rapid growth rates. Although cell growth and division are under the control of the synthesizing machinery in the cell responsible for RNA and protein synthesis, the results indicate that growth is also regulated by membrane-associated transport systems.     

Correlation between cell size and position within the division cycle in suspension cultures of Chang liver cells

Chang liver cells from exponentially growing suspension cultures have been separated by sedimentation at unit gravity. Determinations of the protein content per cell showed that the fractionation procedure resulted in good separation of cells of different size. On the other hand, the DNA content of individual cells from the fractions, as determined cytofluorimetrically, indicated considerable heterogeneity in the size of cells from the same stage of the division cycle. On the basis of earlier results on intermitotic growth and the variation in the length of the cell cycle in homogeneous cell populations, a mathematical model has been constructed and tested using a computer program. The present results on the size distribution of cells from the different stages of the mitotic cycle are consistent with a regeneration of size heterogeneity in each cell generation, as a result of the dispersion of intermitotic times. The variation in cell cycle times may be related to a probabilistic event in the G1 period. In the mathematical model it was necessary to include a mechanism by which the regeneration of abnormally large cells is prevented. The experimental data are compatible with a gradually increasing inhibition of growth in cells larger than a certain size (circa 400 pg protein per cell).     

CORRELATION BETWEEN CELL SIZE AND POSITION WITHIN THE DIVISION CYCLE IN SUSPENSION CULTURES OF CHANG LIVER CELLS

Chang liver cells from exponentially growing suspension cultures have been separated by sedimentation at unit gravity. Determinations of the protein content per cell showed that the fractionation procedure resulted in good separation of cells of different size. On the other hand, the DNA content of individual cells from the fractions, as determined cytofluorimetrically, indicated considerable heterogeneity in the size of cells from the same stage of the division cycle. On the basis of earlier results on intermitotic growth and the variation in the length of the cell cycle in homogeneous cell populations, a mathematical model has been constructed and tested using a computer program. The present results on the size distribution of cells from the different stages of the mitotic cycle are consistent with a regeneration of size heterogeneity in each cell generation, as a result of the dispersion of intermitotic times. The variation in cell cycle times may be related to a probabilistic event in the G₁ period. In the mathematical model it was necessary to include a mechanism by which the regeneration of abnormally large cells is prevented. The experimental data are compatible with a gradually increasing inhibition of growth in cells larger than a certain size (circa 400 pg protein per cell).     

Cell cycle time and rate of entry of cells into mitosis in the small intestine of young rats

Cell cycle time (T(C)) and the rate of entry of cells into mitosis (r(M)) in the jejunum and duodenum of young rats were investigated using the stathmokinetic method. The cell cycle times in the jejunum were 24.3 and 28.3 h in light and dark periods, respectively. Cell cycle times in the duodenum were 17.1 and 21.5 h in light and dark periods, respectively. Rates of entry of cells into mitosis in the jejunum were 1.2 and 1.1 cells/cell/h in light and dark periods and rates of entry of cells into mitosis in the duodenum were 1.4 and 1.8 cells/cell/h in light and dark periods, respectively. Although these changes to cell cycle time values are not statistically significant, the variation between the two periods should be considered in relation to its possible biological effects.     

Yaba virus-specific DNA in the host cell nucleus.

DNA-DNA hybridization studies show that Yaba virus-specific DNA is present in the host cell nucleus late in the infection cycle. The nuclear DNA appears to exist as a complete genome, not convalently linked to host cell DNA, as demonstrated by sedimentation analyses. The DNA apperas to be synthesized in the nucleus, since its level of incorporation of label is ten times the background incorporation detectable in the cytoplasm. Extraction of the nuclei by treatment with SDS and EDTA after precipitation with 1 M NaCl separates most of cellular DNA from the Yaba virus-specific DNA.     

Treatment of mammalian cells with mimosine generates DNA breaks

Exponentially growing mouse erythroleukemia (MEL) cells and quiescent human peripheral blood lymphocytes (PBL) were treated with different concentrations of the nonprotein amino acid mimosine for 16 h. The treatment of the cycling cell population with 400 microM mimosine caused inhibition of DNA replication, changes in the progression of the cells in the cell cycle, and apoptosis. Nucleoid sedimentation analysis and comet assay were used to monitor the appearance and accumulation of DNA breaks. The rate of break accumulation was dose-dependent, did not depend on the stage of the cell cycle and was not connected with the mechanism of DNA replication. The data indicate that the effects of mimosine on DNA synthesis and the cell cycle may be a result of introduction of breaks into DNA.     

Separation of lymphoid-line cells according to volume and density

Velocity sedimentation and isopycnic centrifugation was used to separate exponentially growing RAJI lymphoid line cells according to size and density. Mixtures of Ficoll, Isopaque and tissue culture medium were used as gradient media. These media had a constant pH, were isotonic, and did not have any significant harmful effect on the cells. The observed variation in cell size paralleled the progression of the cells through the cell cycle, as assessed by thymidine incorporation and impulse cytophotometric determination of DNA contents. Differences in cell density did not reflect the cell cycle phase. No correlation could be established between cell size and density. Velocity sedimentation could be used to obtain cell populations which were relatively pure according to cell cycle phase and growing synchronously for at least 24 h.     

A model of cell cycle control: effects of thymidine on synchronous cell cultures.

Further evidence is presented in support of a model for growth control in which commitment for cell division is determined by an event in the preceding cell cycle. A study was made of conditions affecting synchronous growth following treatment of murine mastocytoma cells with excess thymidine at different phases of the cell cycle. Cells were synchronized by a physical procedure involving velocity sedimentation in a zonal rotor. Pulse treatment of such cultures with thymidine at times corresponding to the S, G2, and M periods had no effect on further growth. However, addition at G1, although having no immediate effect, arrested cell growth in the next cell cycle. This temporal effect may account for the decay of synchrony observed during double thymidine blockade or thymidine-FUdR blockade. When the time interval between two such blocks was 7 hr or less, P815Y cells were arrested after one synchronous division. At this critical time a majority of cells were at, or near, G1. It is suggested that thymidine exerts a hitherto unrecognized effect at the G1 interval.     

Significance of the cell cycle in commitment of murine erythroleukemia cells to erythroid differentiation.

The relationship between differentiation of murine erythroleukemia cells (MEL) induced by DMSO and the cell division cycle has been analyzed. We demonstrate that incubation in the presence of DMSO increases the length of the G1 phase of the cell cycle. A method of synchronization of MEL cells by unit gravity sedimentation has been developed and characterized. Using this method, a series of synchronized cell populations covering the entire cell division cycle can be generated simultaneously. Cells synchronized by this technique were challenged with DMSO and analyzed for kinetics of commitment to the differentiation program. Our results indicate that populations of cells in G1 or G2 at the time of addition of inducer give rise to a greater proportion of committed cells than an unfractionated population, while cells in S phase result in a lower percentage of committed cells than the unfractionated population when cultured in DMSO.     

Repair of radiation-induced DNA strand scissions inChlorella during the cell cycle

Summary In the first part of our studies DNA sedimentation behaviour during a mitotic cycle of the unicellular green algaChlorella pyrenoidosa was investigated. In the S-phase a decrease in sedimentation rate of akaline-denatured DNA could be observed. Alkaline sucrose density gradient analysis was used to examine the repair of radiation-induced single strand breaks in DNA in various stages of the cell cycle. Three characteristic phases of the growth period were chosen: autospore phase, early beginning of DNA replication and maximum DNA synthesis. Our results indicate that DNA damage is different within the cell cycle, but the repair of radiation-induced DNA strand scissions is only to a small degree dependent on the cell stage.This work was supported, by the IAEA under Project Number 794/CF as a part of a coordinated programme of research, on the study and improvement of biopheres resources.     

The effects of 5α-dihydrotestosterone on the kinetics of cell proliferation in rat prostate

The regenerating rat prostate was used as an experimental model to determine the effects of 5alpha-dihydrotestosterone on certain parameters of cell proliferation, including the duration of the phases of the cell cycle and the size of the cellular growth fraction. Rats castrated 7 days previously were treated with daily subcutaneous injections of 5alpha-dihydrotestosterone for 14 days; 48h after the beginning of therapy, cells in the process of DNA synthesis were labelled with a single injection of radioactive thymidine and the progress of these cells through the division cycle was observed. Cell-cycle analysis was performed by fractionating prostatic nuclei according to their position in the cell cycle by using the technique of velocity sedimentation under unit gravity. The results indicate that during regeneration the cell population undergoes 1.8 doublings with a doubling time of 40h, and that the process involves almost four rounds of cell division with a cell-generation time of 20h. The growth fraction at any time is about 0.5, and about half the daughter cells produced do not re-enter the proliferative cycle. All cells present at the start of regeneration eventually undergo at least one division during the course of regeneration, although any given cell can divide from one to four times.     

STUDIES OF NATIVE GLYCOGEN ISOLATED FROM SYNCHRONIZED TETRAHYMENA PYRIFORMIS (HSM)

Native glycogen was isolated from Tetrahymena pyriformis (HSM) by isopycnic centrifugation in cesium chloride density gradients. A density of 1.62 to 1.65 was isopycnic for glycogen. Most of the banded glycogen existed as 35 to 40 mµ particles which had a sedimentation coefficient of 214. These particles were composed of aggregates of 2 to 3 mµ spherical particles. Extraction of glycogen with hot alkali reduced the sedimentation coefficient of native glycogen from 214 to 64.7 and the particle diameter from approximately 40 to 20 mµ and smaller. Cell division was synchronized by a repetitive 12-hour temperature cycle, and glycogen was measured at several times during the cell cycle. The temperature cycle consisted of 9.5 hours at 12°C and 2.5 hours at 27°C. Approximately 90 per cent of the cells divided during the last 1.5 hours of the warm period. The carbohydrate/protein ratio of cells at the end of the cold period was 0.27 and was reduced slightly during the warm period. Glucose was incorporated into glycogen during both periods, although the rate of incorporation was greater during the warm period. No preferential incorporation on the basis of particle size was noted. Incorporation was measured in both native glycogen and KOH-extracted glycogen. Tetrahymena glycogen is compared with rat liver glycogen previously isolated by similar procedures, and the significance of using combined rate-zonal and isopycnic centrifugation for isolating native glycogen is discussed.     

Resonance in periodic chemotherapy: a case study of acute myelogenous leukemia

The effects of periodic chemotherapy administration are evaluated within the context of a G(0)model of the cell cycle. Parameters are estimated for normal bone marrow cells and malignant cells in acute myelogenous leukemia (AML). This model explicitly includes the resting G(0)phase and the feedback mechanism that recruits the cells back into the cell cycle. Periodic chemotherapy administration can induce resonance within our model under high cell kill rate where the average cell cycle times may change during the course of treatment, and therapeutic benefits from these resonances cannot be solely based on cell cycle times in untreated tissue. The depletion rate under chemotherapy and the regrowth rate may differ between the cell populations, and our analysis suggests that this favors the tumour cells. We were able to distinguish between the effects of cycle-non-specific, S -phase-specific and M -phase-specific drugs, and found that these can show differences in sharpness and location of the resonance phenomenon. We conclude that resonance chemotherapy (chronotherapy) is unlikely to be efficacious in the treatment of AML.     

Assessment of blood echogenicity as an alternative measure to erythrocyte sedimentation rate.

OBJECTIVE--To determine the relation between erythrocyte sedimentation rate and blood echogenicity and whether measurement of erythrocyte sedimentation rate could be replaced by measurement of blood echogenicity in monitoring acute phase reactions. DESIGN--Simultaneous measurement of echogenicity of flowing blood and erythrocyte sedimentation rate in blood samples and comparison of results. SETTING--A radiological department in a university hospital. SUBJECTS--83 patients with a suspected venous thrombosis and 36 healthy volunteers. MAIN OUTCOME MEASURES--Correlations between the erythrocyte sedimentation rate, packed cell volume, and echogenicity of flowing blood. RESULTS--Blood echogenicity correlated poorly with the packed cell volume, but strongly correlated with the erythrocyte sedimentation rate (when the packed cell volume was within reference limits) (correlation coefficient = 0.73). Blood samples with a greatly raised erythrocyte sedimentation rate were highly echogenic. Only one of the 30 samples with an erythrocyte sedimentation rate below 10 mm in first hour had a higher echogenicity than the least echogenic sample of the 19 with a sedimentation rate above 30 mm in first hour. CONCLUSIONS--Echogenicity of flowing blood correlates with the erythrocyte sedimentation rate and its measurement may compete with conventional methods for evaluating the long term changes in acute phase reactions. Also, it has the added advantage that non-invasive in vivo measurements of blood echogenicity may become possible.     

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.     

Preparation and characterization of Cryptococcus neoformans synchronous culture

We have developed a method for preparation of synchronous culture in Cryptococcus neoformans. The method is based on age fractionation of exponentially growing asynchronous culture through differential sedimentation in 10-20% (w/v) lactose gradient. C. neoformans capsule thickness should be reduced to a minimum to ensure most accurate age fractionation, which is necessary to obtain a higher degree of synchrony. The C. neoformans synchronous culture system has revealed important characteristics with respect to cellular morphology, DNA content and cell volume distribution. The method can be used for further cell cycle studies.