Comparison of synchronized Chinese hamster ovary cells obtained by mitotic shake-off, hydroxyurea, aphidicolin, or methotrexate

Synchronized cell populations are necessary to study many aspects of cell biology. We have developed a method to obtain highly synchronized Chinese hamster ovary cell populations in S phase or G2 phase by utilizing mitotic selection followed by incubation with either hydroxyurea, aphidicolin, or methotrexate for 12 h. Flow cytometry analysis shows that the coefficient of variation in the spread of the cell population in S phase is as low as 6%. Drug toxicity studies compare the effects of the various drugs on G1 and S phase cells. The use of aphidicolin or hydroxyurea results in the most highly synchronized cell populations, but methotrexate yields inadequate synchronization. These results demonstrate that both aphidicolin and hydroxyurea are useful drugs for obtaining highly synchronized cell populations after an initial synchrony in mitosis. Aphidicolin is perhaps the best choice because of less toxicity to S phase cells when used in low concentrations.     

An improved method for the cell cycle synchronization of <Emphasis Type="Italic">Vicia faba</Emphasis> root meristem cells

Plant root meristem cells divide asynchronously which makes biochemical analysis of cell cycle regulation particularly difficult. In the present article a high level of cell cycle synchronization in Vicia faba root meristems was obtained by using a rich medium (HNS), special culture conditions and a double-block method with replication inhibitor—hydroxyurea (HU). Two HU concentrations were tested and different periods of the first and the second synchronization, and of cycle recommencement between the first and the second blockage. The level of synchronization was estimated on the basis of ³H-thymidine labeling indices, mitotic, and phase indices and indices determining the percentage of G1 and G2 cells, which were identified by cytophotometric measurements of DNA content in individual nuclei. The highest level of cell cycle synchronization was obtained after double treatment of meristems with 1.25 mM HU (18 and 12 h) separated by 6-h incubation in HNS without HU. During the second postincubation in HNS in subsequent hours: 4, 7, 10, 11, over 90% of cells in the S phase, nearly 70% in G2 phase, 86% in mitosis, and nearly 70% in G1 phase were received, respectively. The use of 2.5 mM HU in a similar experimental procedure caused disturbed divisions.     

Synthesis and secretion of light-chain immunoglobulin in two successive cycles of synchronized plasmacytoma cells

Suspension-cultured mouse plasmacytoma cells (MPC-11) were accumulated in the late G1 phase by exposure to isoleucine-deficient medium for 20- 24 h. The arrested culture was fed with complete medium enabling the cells to continue the cell cycle synchronously, undergo mitosis, and enter a second cycle of growth. This method of synchronization left the protein-synthesizing ability intact as judged by the polysome profile and the capacity of the cells to incorporate labeled amino acids into protein after the restoration of isoleucine. After incubation in isoleucine-deficient medium and the addition of isoleucine to the culture, cells entered the S phase after a short lag, as judged by [3H]thymidine incorporation into nucleic acid and by spectrophotometric measurement of nuclear DNA. The cells were in mitosis between 12 and 18 h as judged by the increase in cell count and analysis of cell populations on albumin gradients. Synthesis and secretion of light- chain immunoglobulin were maximal in the late G1/early S phase of the first cycle. During late S phase, G2 phase, and mitosis, both synthesis and secretion were observed to be at a low level; however, immediately after motosis the cells which then entered the G1 phase apparently commenced synthesis of light chain immunoglobulin straight away, although secretion of labeled material remained at a low level.     

A method of synchronization of normal and malignant human cells in culture.

A method is described for providing reproducible S phase parasynchrony in both normal mesenchyme and transformed epithelia. Cells were seeded at low density in medium containing 10% serum. 24 h later the serum concentration was reduced to 0.5%. After 110th the cells were collected at the G1/S boundary in fresh medium containing 10% serum plus 2.5mM hydroxyurea over 20h. After removal of hydroxyurea and trypsinization the re-plated cells entered the S phase with a high degree of synchrony, as judged by autoradiography, pulse-labelling with 3H-thymidine, cell growth and time lapse cinematography. By 6h after synchronization 80% of the population had entered the S phase and between 10-13h 70% went through mitosis.     

Hydroxyurea treatment affects the G1 phase in next generation CHO cells

DNA replication kinetics were studied in populations of synchronized CHO cells treated in the previous generation with hydroxyurea. These CHO cells were re-synchronized by selective detachment of mitotic cells after previously synchronized G1 traversing cultures were treated with 0.1 mM and 2 mM hydroxyurea for 9 and 13 h. Our results show that these cells exhibit a shortening of G1 of at least 1 h relative to cells selected in mitosis from untreated exponentially growing cultures. Survival studies indicated that the hydroxyurea treatments did not affect plating efficiencies. Cell viability was reduced when the initially synchronized populations were blocked with 2 mM, but not 0.1 mM hydroxyurea for greater than 13 h. DNA replication measurements after these blocks showed that all cultures treated with 2 mM hydroxyurea for either 9, 13 or 15 h were blocked at the same point near the G1/S boundary, and then progressed through S phase with similar kinetics. The observed shortening of G1 in the next generation of these cells was independent of both the concentration (0.1 or 2.0 mM) and the time (9 or 13 h) of the hydroxyurea block. These results suggest that specific events relating to the next cell generation can be uncoupled from DNA synthesis and can occur when hydroxyurea inhibits normal cell cycle traverse of G1 cells into and through S phase.     

Correlation between cell cycle duration and RNA content.

The metachromatic fluorochrome acridine orange was used to differentially stain DNA and RNA in Chinese hamster ovary (CHO) cells and in mitogen-stimulated human lymphocytes during their progression through the cell cycle. Green and red fluorescence of individual cells, representing cellular DNA and RNA, respectively, was measured by flow cytometry. CHO cells were synchronized by selective detachment at mitosis. Their rate of progression through G1 and subsequently through S phase correlated with the content of stainable RNA. The mean duration of the G1 phase was 5.2 hours for cells with high RNA content (highest 25 percentile population) and 8.1 hours for cells with low RNA (lowest 25 percentile). The duration of S phase was 5.9 and 7.5 hours for high- and low-RNA, 25 percentile subpopulations, respectively. Lymphocytes synchronized at the G1/S boundary by hydroxyurea or 5-fluorodeoxyuridine showed extremely high intercellular variation with respect to content of stainable RNA. After release from the block they traversed S phase at rates linearly proportional to the content of stainable RNA. The duration of S phase was five hours for cells with high RNA-, six to nine hours for cells with moderate RNA- and up to 27 hours for cells with minimal RNA-content. The data suggest that the rate of progression through the cell cycle of individual cells within a population may be correlated with the number of ribosomes per cell.     

EFFECTS OF HYDROXYUREA ON THE KINETICS OF COLONY FORMING UNITS OF BONE MARROW IN THE MOUSE

The number of nucleated bone marrow cells, the number of CFU and the number of DNA-synthesizing cells in the mouse were studied after injection of hydroxyurea. It was found that one injection provokes a partial synchronization of surviving cells and probably stimulates the transition of CFU from the quiescent to the cycling state. the changes of the proportion of CFU in the S phase makes it possible to estimate approximately a cell cycle duration of about 12 hr.     

鹰嘴紫云英根尖细胞有丝分裂同步化诱导

采用羟基脲和氟乐灵结合的双阻断方法处理鹰嘴紫云英根尖,以诱导根尖细胞有丝分裂中期同步化。结果表明,用1．25mmol．L^-1羟基脲处理18h和1μmol·L^-1氟乐灵处理6h的细胞有丝分裂中期指数可达80％,且有丝分裂正常,染色体形态良好,未见到染色体畸变的现象。     

Immunocytochemical study of cell cycle control by cytokinin in cultured soybean cells

An immunocytochemical method was used to determine the proportion of cells in the DNA synthesis (S phase) of the mitotic cycle in suspension cultures of soybean (Glycine max (L.) Merr. cv. Acme) callus of cotyledonary origin, the stably cytokinin-dependent tissue used in the cytokinin bioassay devised by Carlos O. Miller. A standard cell synchronization protocol involving hydroxyurea was used to demonstrate the applicability of the immunocytochemical method to this cell culture. Cells were brought to mitotic arrest by cytokinin withdrawal, and the cell division cycle was restarted by the addition of cytokinin. We have followed the pattern of resumption of S phase after the readdition of cytokinin. This pattern reveals the existence of three subpopulations of cells in cytokinin-starved cultures, consistent with the occurrence of three cytokinin-requiring events in the cell cycle: one in mitosis, one in S phase, and one in the G₁ phase.Abbreviations BrdU 5-bromo-2-deoxyuridine - DI deionized water - FITC fluorescein isothiocyanate - HU hydroxyurea - l-AOPP l--aminooxy--phenylpropionic acid - LI labeling index - PA polyamine - PI propidium iodide     

Cell synchrony techniques. I. A comparison of methods

Selected cell synchrony techniques, as applied to asynchronous populations of Chinese hamster ovary (CHO) cells, have been compared. Aliquots from the same culture of exponentially growing cells were synchronized using mitotic selection, mitotic selection and hydroxyurea block, centrifugal elutriation, or an EPICS V cell sorter. Sorting of cells was achieved after staining cells with Hoechst 33258. After synchronization by the various methods the relative distribution of cells in G1, S, or G2 + M phases of the cell cycle was determined by flow cytometry. Fractions of synchronized cells obtained from each method were replated and allowed to progress through a second cell cycle. Mitotic selection gave rise to relatively pure and unperturbed early G1 phase cells. While cell synchrony rapidly dispersed with time, cells progressed through the cell cycle in 12 hr. Sorting with the EPICS V on the modal G1 peak yielded a relatively pure but heterogeneous G1 population (i.e. early to late G1). Again, synchrony dispersed with time, but cell-cycle progression required 14 hr. With centrifugal elutriation, several different cell populations synchronized throughout the cell cycle could be rapidly obtained with a purity comparable to mitotic selection and cell sorting. It was concluded that, either alone or in combination with blocking agents such as hydroxyurea, elutriation and mitotic selection were both excellent methods for synchronizing CHO cells. Cell sorting exhibited limitations in sample size and time required for synchronizing CHO cells. Its major advantage would be its ability to isolate cell populations unique with respect to selected cellular parameters.     

CELL KINETIC ALTERATIONS IN NORMAL AND NEOPLASTIC CELL POPULATIONS IN VITRO AND IN VIVO FOLLOWING VINCRISTINE*. A REPLY TO DR CAMPLEJOHN'S REVIEW ARTICLE†

It is shown that the lethal action of vincristine (VCR) is dose-dependent and may occur at interphase and mitosis. In general, the VCR dose used to destroy cells must be approximately ten times higher than that used to arrest cells in mitosis at metaphase. There is strong evidence that cells can survive metaphase arrest by a sublethal dose of VCR either completing cytokinesis normally after metabolism of the drug or becoming polyploid because of an impaired mitotic spindle apparatus. These cells are not doomed to die, at least in some cell systems. Furthermore, there is strong evidence in three animal tumour systems (transplantable and autochthonous tumours) that VCR is able to induce in vivo partial synchronization of proliferating tumour cells and/or recruitment of resting cells into the proliferating compartment. Failures to induce partial synchrony in cell populations by VCR may be attributed to resistance to VCR or cytolysis or slow proliferation of cells in badly vascularized tumours. Chemotherapy after synchronization seems to be effective as shown by non-randomized trials in bad-risk patients with solid tumours and acute leukaemias. In a randomized co-operative trial results of the two-drug synchronization protocol in patients with non-Hodgkin's lymphoma of high grade malignancy were statistically better than those of a four-drug protocol (COPP) established empirically. The two-drug protocol was equally effective as the four-drug protocol in Hodgkin's disease. Side-effects were less pronounced with the so-called synchronization scheme.     

Emergence of Micronuclei and Their Effects on the Fate of Cells under Replication Stress

The presence of micronuclei in mammalian cells is related to several mutagenetic stresses. In order to understand how micronuclei emerge, behave in cells, and affect cell fate, we performed extensive time-lapse microscopy of HeLa H2B-GFP cells in the presence of hydroxyurea at low concentration. Micronuclei formed after mitosis from lagging chromatids or chromatin bridges between anaphase chromosomes and were stably maintained in the cells for up to one cell cycle. Nuclear buds also formed from chromatin bridges or during interphase. If the micronuclei-bearing cells entered mitosis, they either produced daughter cells without micronuclei or, more frequently, produced cells with additional micronuclei. Low concentrations of hydroxyurea efficiently induced multipolar mitosis, which generated lagging chromatids or chromatin bridges, and also generated multinuclear cells that were tightly linked to apoptosis. We found that the presence of micronuclei is related to apoptosis but not to multipolar mitosis. Furthermore, the structural heterogeneity among micronuclei, with respect to chromatin condensation or the presence of lamin B, derived from the mechanism of micronuclei formation. Our study reinforces the notion that micronucleation has important implications in the genomic plasticity of tumor cells.     

Circadian rhythm of the mitotic activity and of the number of nuclei synthesizing DNA in sarcoma 37 in white mice]

Circadian variations in the frequency of mitoses and the number of nuclei labed with thymidine-H3 in sarcoma-37 of mice were investigated. It was shown that the circadian rhythm of mitotic activity was composed of diurnal variations in the frequency of labeled and unlabeled mitoses. The G2-phase of mitotic cycle of the cells with labeled mitosis was approximately one hour. The G2-phase of the cells with unlabed mitosis lasted four hours and more. It is suggested that there are two cell populations in sarcoma-37.     

The synchronizing effect of cyclic 3',5'-adenosine monophosphate on the mitotic cycle of Ehrlich ascitic carcinoma cells]

A study was made of the number of mitoses and of the DNA-synthesizing cells in the ascitic Ehrlich carcinoma in the course of 24 hours after the injection of cyclic 3',5'-adenosinmonophosphate to mice. It was found that as the result of the preprrophase inhibition and, possibly, of stimulation of the cell entry into the S-phase, 8 hours after the action a great number of cells began to divide almost simultaneously. The effect of mitosis synchronization was assessed in the tumour cell population.     

Induction of Cell Death by Cytokines in Cell Cycle-Synchronous Tumor Cell Populations Restricted to G1and G2

In the present work, cytokine-mediated induction of cell death was investigated by flow cytometry in cell cycle-synchronous human tumor cell populations gained by centrifugal elutriation or by cell cycle blockade with mimosine and aphidicolin. Attention was payed to the question of whether the effector phase of cell death takes place in the same phase of the cell cycle in which the death signal is received. Another point of interest was the question whether synchronization of cell populations with respect to the cell cycle leads to increased synchronicity of the death phase. The results demonstrate that supernatants from monocyte/tumor cell interaction cultures containing tumor necrosis factor-α, interferons, and interleukins-1 and -6 or appropriate combinations of pure cytokines cause cell cycle arrest predominantly in G₁and to a lesser extent in G₂. Cell death is initiated from both arrest points. Cytokine-treated G₁cells do not enter S phase. They die within the same G₁phase in which they receive the death signal. In contrast, a high proportion of cytokine-treated G₂cells pass through mitosis and are arrested and die in the subsequent G₁phase, whereas only a smaller proportion of cells are arrested and die in G₂. The synchronicity of the death phase cannot be increased by the diverse methods of cell cycle synchronization applied. Interestingly, aurin-tricarboxylic acid, an agent known for inhibitory effects on nucleolytic activities and other protein/nucleic acid interactions, not only prevents cell death, but also cell cycle arrest.     

Cell Synchrony Techniques. I. A Comparison of Methods

Abstract Selected cell synchrony techniques, as applied to asynchronous populations of Chinese hamster ovary (CHO) cells, have been compared. Aliquots from the same culture of exponentially growing cells were synchronized using mitotic selection, mitotic selection and hydroxyurea block, centrifugal elutriation, or an EPICS V cell sorter. Sorting of cells was achieved after staining cells with Hoechst 33258. After synchronization by the various methods the relative distribution of cells in G₁ S, or G₂+ M phases of the cell cycle was determined by flow cytometry. Fractions of synchronized cells obtained from each method were replated and allowed to progress through a second cell cycle. Mitotic selection gave rise to relatively pure and unperturbed early G₁ phase cells. While cell synchrony rapidly dispersed with time, cells progressed through the cell cycle in 12 hr. Sorting with the EPICS V on the modal G₁ peak yielded a relatively pure but heterogeneous G₁ population (i.e. early to late G₁). Again, synchrony dispersed with time, but cell-cycle progression required 14 hr. With centrifugal elutriation, several different cell populations synchronized throughout the cell cycle could be rapidly obtained with a purity comparable to mitotic selection and cell sorting. It was concluded that, either alone or in combination with blocking agents such as hydroxyurea, elutriation and mitotic selection were both excellent methods for synchronizing CHO cells. Cell sorting exhibited limitations in sample size and time required for synchronizing CHO cells. Its major advantage would be its ability to isolate cell populations unique with respect to selected cellular parameters.     

The effects of cyclosporins on the cell cycle of T-lymphoid cell lines

Cyclosporin A (CsA) is a cyclic endecapeptide of fungal origin displaying strong immunosuppressive properties. CsA and another active member of the cyclosporin (Cs) family, but not an inactive one, can interfere with the proliferation of some, but not all, T-lymphoid cell lines. Cells from Cs-sensitive lines accumulate in the G1 phase of the cell cycle. No effect is detected on the cycle of Cs-resistant lines. Both Cs-sensitive and Cs-resistant lines are arrested by another G1 blocker (actinomycin D) and DNA synthesis inhibitors (cytosine arabinoside, hydroxyurea), become multinucleated/polyploid when exposed to cytochalasin B (CB), are arrested in mitosis by colchicine and accumulate in G2 phase in the presence of Taxol. The effect of Cs is best evidenced when the drug is applied to cells which were already delayed in G1 by saturation density cultivation or serum deprivation. By the combined use of Cs and of other drugs working at a later phase of the cycle, results were obtained which suggest that the effect of Cs is either to delay very much the cells throughout the G1 phase or to arrest them at that G1 phase or at the following one. A correlation of the G1-blocking property of Cs with their immunosuppressive properties may be possible but is still speculative.     

Cell cycle analysis of sodium butyrate and hydroxyurea, inducers of ectopic hormone production in HeLa cells

Sodium butyrate and hydroxyurea, effective inhibitors of DNA synthesis in HeLa cells, cause these cells to produce increased levels of the ectopic glycopeptide hormones human chorionic gonadotropin (hCG), follicle stimulating hormone (FSH), and free alpha chains for these hormones. The objective of this study was an assessment of the role of modulation of cell cycle events in the action of these two chemical agents. A variety of experimental approaches was employed to obtain a clear view of the drugs' effects on cells located initially in all phases of the cell cycle. Cells in early G1, G2, or M phase at time of addition of either inhibitor were not arrested at early time points, but by 48 hours became collected at a location characteristic for each drug, near the G1-S phase boundary. Flow microfluorometry (FMF) and thymidine labeling index revealed that butyrate-treated cells arrested late in G1 phase very close to S phase, while hydroxyurea-blocked cells continued to early S phase. Both inhibitors prevented cells originally in S phase from reaching mitosis. S cells exposed to hydroxyurea were killed by 48 hours, but those growing in 5 mM butyrate progressed to the end of S or G2 phase where they became irreversibly arrested although not removed from the monolayer. Analysis of the cell cycle location and viability of each subpopulation resulting from 48 hour exposure to butyrate or hydroxyurea is important for the study of the function of each cellular subset. Treatment of HeLa cells with lower concentrations of butyrate (1 mM) resulted in slowed yet exponential growth. Fraction labeled mitosis (FLM) analysis shows that this is a result of prolongation of the G1 phase.     

Cell cycle variations in chromatin structure detected by DNase I

We have recently developed a reproducible method for the use of DNase I as a sensitive probe of chromatin structure (Prentice, D A & Gurley, L R, Biochim biophys acta 740 (1983) 134) [12] and have used this probe to investigate chromatin structure during the interphase of the cell cycle. Chinese hamster cells (line CHO) were synchronized by: (1) mitotic detachment, to obtain M-phase cells; (2) isoleucine deprivation, to obtain G1-phase cells; and (3) sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea, to obtain cells blocked at the start of S phase. The cells were released from the various blocking schemes and nuclei were isolated and digested with DNase I at various times. The digestion kinetics were monitored to detect possible changes in chromatin condensation through the cell cycle. The chromatin was much more accessible to DNase I in G1 phase than in S or G2 phase, with only small variations in structure detected in late G1 and very early S phase. From early S phase up to mitosis, the chromatin became increasingly condensed and inaccessible to DNase I action. These results support the concept of a chromatin condensation cycle during interphase as well as during mitosis.