A two-parameter flow cytometry protocol for the detection and characterization of the clastogenic, cytostatic and cytotoxic activities of chemicals

Cultured, freshly-isolated rat fibroblasts were exposed in vitro to vincristine sulphate (VC), amethopterin (AM), bleomycin (BL), benomyl (BE) and practolol (PR). Cells treated for 5 h were subjected 24 h later to a two-parameter (DNA/protein) flow cytometry analysis. The fluorochromes used were sulphorhodamin 101 and DAPI. From DNA and protein histograms, alterations in cell-cycle kinetics, variations in the amount of DNA in individual G1-phase cells and the enhancement of or increased variation in the protein content of the exposed cells were determined. Each of the 5 chemicals induced a specific dose-dependent pattern of changes in the DNA and protein histograms. DNA dispersion was enhanced with VC, AM, BL and BE but not with PR. The cell cycle was blocked in the G2 phase with VC, at early S phase with amethopterin and, depending on the dose, at the G1 or G2 phase with bleomycin or at the S phase or G2 phase with benomyl. Practolol inhibited cells slightly in the S phase at the highest exposure level. Protein analysis allows cytotoxic activity (loss of proteins) or induced unbalanced growth (protein accumulation) of test compounds to be recognized. The results obtained imply that the proposed two-parameter DNA/protein analysis by flow cytometry is a suitable method for prospective testing of chemicals for their induction of structural or numerical chromosome aberrations. Simultaneously, a broad range of cytotoxic, cytostatic and cell-cycle perturbing activities of the test agents can be recognized.     

The relation between protein accumulation and cell cycle traverse of human NHIK 3025 cells in unbalanced growth

Human NHIK 3025 cells, synchronized by mitotic selection, were given 2 mM thymidine, which inhibited DNA synthesis without reducing the rate of protein accumulation. After removal of the thymidine the cells proceeded towards mitosis and cell division, with an S duration 2 hours shorter than, but a G2 and M duration nearly identical to that of the control cells. If cycloheximide (1.25 m?M) was present together with thymidine, no net protein accumulation took place during the treatment, and the subsequent duration of S, G2, and M was similar to that of the untreated cells. The shortening of S seen after treatment with thymidine alone would therefore indicate that the rate of DNA synthesis depended on the amount of some preaccumulated protein. The postreplicative period in thymidine-treated cells was lengthened by cycloheximide treatment although the protein content had already been doubled. This suggests that proteins required for the traverse of this part of the cell cycle might have to be synthesized after completion of DNA replication. Shortly after removal of thymidine, the rate of protein accumulation declined markedly, indicating the existence of some mechanism for negative control of cell mass. In addition, the daughters of thymidine-treated cells had their cell cycle shortened by 2 hours. As a result, the cells had returned to balanced growth already in the first cell cycle following the induction of unbalanced growth. In conclusion, our experiments suggest that NHIK 3025 cells might require a minimum time in order to traverse the cell cycle, which is independent of cell mass.     

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.     

Unbalanced growth and cell death in HeLa S3 cultures treated with DNA synthesis inhibitors

Flow cytometry indicated that significant amounts of dsRNA were accumulated in HeLa S3 cells blocked at or near G₁/S boundary by hydroxyurea (HU) or excess thymidine (TdR). The dsRNA/DNA ratio increased in these cells in a manner characteristic of unbalanced cell growth. In HU-treated cells, dsRNA content was maximal 16 hours after addition of the drug and did not change significantly during the next 24 hours. The DNA content in blocked cells increased by 10%. Cell viability assessed by colony formation in soft agar decreased exponentially in HU-treated cultures after 16 hours of incubation. Correlation between loss of cell viability and rate of cell proliferation after removal of HU was observed, as determined by cell count and analysis of cell cycle progression. In TdR-treated cultures cells slowly progressed into mid S-phase during 40 hours and dsRNA accumulation continued during this period. Cell viability was not significantly affected by treatment with excess TdR, indicating that unbalanced growth per se, as measured by dsRNA accumulation, is not lethal for the cells. After reversal of DNA synthesis inhibition by removal of the drug, cells treated with HU for 16 hours or TdR for 16–24 hours promptly progressed through the cell cycle. This progression was accompanied by accumulation of significant amounts of dsRNA. As a result, cells in G₂ phase had a very high dsRNA content leading to retention of the unbalanced condition (increased dsRNA/DNA ratio) in the daughter cells. It is suggested that dsRNA accumulation in the cell is controlled to a certain degree by cell progression through the S phase. This type of control, evidently, was reflected in limited dsRNA accumulation in the cells blocked at or near G₁/S border, in continuous dsRNA accumulation in the cells slowly progressing through S phase, and in accumulation of large amounts of dsRNA after renewal of progression through the S phase.     

用双参数流式细胞光度术(FCM)研究阿克拉霉素对L_(1210)白血病细胞周期的影响

本文用双参数FCM技术,对同一个细胞的DNA和RNA含量进行相关测量,比较了ACM B对小鼠L_(1210)白血病细胞周期和RNA含量的影响.结果发现在一次给药后8小时可导致早、中期S的积累,并抑制S期细胞的DNA合成;到24小时DNA合成恢复正常,并进入G_2期,但由于G_2期细胞进入M期受阻,造成G_2期细胞的积累,这时被阻断在G_2期的细胞RNA含量显著增加,形成正不平衡生长,而给药剂量较大的实验组(1/1.5LD_(50))S期细胞的RNA含量不随着DNA含量的增加而增加,形成负不平衡生长,ACM A和ACM B对体内Li_(210)细胞周期作用相同.     

Inhibition of endothelial cell proliferation by platelet factor-4 involves a unique action on S phase progression

Modulation of endothelial cell proliferation and cell cycle progression by the "chemokine" platelet factor-4 (PF-4) was investigated. PF-4 inhibited DNA synthesis, as well as proliferation of endothelial cells derived from large and small blood vessels. Inhibition by PF-4 was independent of the type and the concentration of stimuli used for the induction of endothelial cell proliferation. Inhibition of cell growth by PF-4 was reversible. The effects of PF-4 were antagonized by heparin. Cell cycle analysis using [3H]thymidine pulse labeling during traverse of synchronous cells from G0/G1 to S phase revealed that addition of PF-4 during G1 phase completely abolished the entry of cells into S phase. In addition, PF-4 also inhibited DNA synthesis in cells that were already in S phase. In exponentially growing cells, addition of PF-4 resulted in an accumulation of > 70% of the cells in early S phase, as determined by FACS (Becton-Dickinson Immunocytometry Systems, Mountain View, CA). In cells synchronized in S phase by hydroxyurea and then released, addition of PF-4 promptly blocked further progression of DNA synthesis. These results demonstrate that in G0/G1-arrested cells, PF-4 inhibited entry of endothelial cells into S phase. More strikingly, our studies have revealed a unique mode of endothelial cell growth inhibition whereby PF-4 effectively blocked cell cycle progression during S phase.     

The adenovirus E1A protein overrides the requirement for cellular ras in initiating DNA synthesis.

The adenovirus E1A protein can induce cellular DNA synthesis in growth-arrested cells by interacting with the cellular protein p300 or pRb. In addition, serum- and growth factor-dependent cells require ras activity to initiate DNA synthesis and recently we have shown that Balb/c 3T3 cells can be blocked in either early or late G1 following microinjection of an anti-ras antibody. In this study, the E1A 243 amino acid protein is shown through microinjection not only to shorten the G0 to S phase interval but, what is more important, to override the inhibitory effects exerted by the anti-ras antibody in either early or late G1. Specifically, whether E1A is co-injected with anti-ras into quiescent cells or injected 18 h following a separate injection of anti-ras after serum stimulation, it efficiently induces cellular DNA synthesis in cells that would otherwise be blocked in G0/G1. Moreover, injection of a mutant form of E1A that can no longer associate with p300 is just as efficient as wild-type E1A in stimulating DNA synthesis in cells whose ras activity has been neutralized by anti-ras. The results presented here show that E1A is capable of overriding the requirement of cellular ras activity in promoting the entry of cells into S phase. Moreover, the results suggest the possibility that pRb and/or pRb-related proteins may function in a ras-dependent pathway that enables E1A to achieve this activity.     

Simian virus 40 induces multiple S phases with the majority of viral DNA replication in the G2 and second S phase in CV-1 cells

The infection of permissive monkey kidney cells (CV-1) with simian virus 40 induces G1 growth-arrested cells into the cell cycle. After completion of the first S phase and movement into G2, mitosis was blocked and the cells entered another DNA synthesis cycle (second S phase). Growth-arrested CV-1 cells replicated significant amounts of viral DNA in the G2 phase with the majority of synthesis occurring during the second S phase. When mimosine-blocked (G1/S) infected cells were released into the cell cycle, a major portion of the viral DNA was detected in G2 with the largest accumulation in the second S phase. The total DNA produced per infected cell was 10-12C with approximately 0.5-2C of viral DNA replicated per cell. Therefore the majority of the DNA per cell was cellular, 4C from the first S phase and approximately 4-6C from the second cellular synthesis phase.     

Butyrate inhibits mouse fibroblasts at a control point in the G1 phase

Butyrate block 3T6 cells in the G1 phase of the cell cycle approximately 5--6 h prior to the start of the S phase. Serum factors are required before as well as after the butyrate-sensitive steps in G1 in order to allow cells to start DNA synthesis. 3T6 cells infected with SV40 or with polyoma virus are also blocked at the same stage in G1 in the presence of the fatty acid. However, events before as well as after the butyrate-sensitive step do not require serum in virus-infected cells. The sensitivity of the initiation of cellular DNA synthesis to increasing concentrations of butyrate is the same for serum-stimulated or for virus-infected cells. A similar and parallel effect on DNA synthesis is observed if cells are incubated in the presence of very small amounts of cycloheximide. After release of the cycloheximide-induced G1 arrest about 4--6 h have to pass before cells enter the S phase. Cells stably transformed by SV40 are considerably more resistant to low cycloheximide concentrations and to butyrate. These data are discussed in the light of the hypothesis that both low concentrations of cycloheximide and sodium butyrate block cells at a control point in G1 by interference with the synthesis of one or more rapidly turning over, cell cycle-specific proteins.     

Evidence for new cellular proteins which may negatively control DNA replication or cell growth in rat 3T3 fibroblasts

When separated and proliferating rat 3T3 cells are treated with butyrate (6 mM), DNA synthesis stops within 24 h, while RNA and protein synthesis proceed unaffected. This gradually converts normal cells into giant ones in the presence of butyrate (volume up to 30-fold greater). The giant cells stop growing when cell to cell contact is established. By studying the rate of synthesis of 300 cell proteins, we have identified two proteins (39 kDa, PI = 6.2, and 60 kDa, pI = 5.6) whose synthesis rises at least 10-fold when DNA replication and mitosis are prevented following intercellular contact or butyrate treatment, and another (64 kDa, pI = 5.6) whose synthesis rises at least 10-fold when cell growth stops by contact, both in the presence of butyrate and in the absence of butyrate (untreated confluent cells). The synthesis of some cellular oncogenes increases when the cell transits from G0 to S phase; the two proteins of 39 and 60 kDa described here are regulated in the opposite direction, their synthesis is enhanced when the cell leaves the proliferation cycle to enter G0.     

低氧对肺动脉内皮细胞PDGF—B链释放及平滑肌细胞生长的影响

应用蛋白ｄｏｔｂｌｏｔ技术检测了低氧内皮细胞条件培养液（ＨＥＣＣＭ）和常氧内皮细胞条件培养液（ＮＥＣＣＭ）内ＰＤＧＦ相对含量,并利用［３Ｈ］－ＴｄＲ掺入法和流式细胞术观察了ＨＥＣＣＭ和ＮＥＣＣＭ及加入特异ＰＤＧＦ抗体对肺动脉平滑肌细胞（ＰＡＳＭＣ）生长的影响。结果表明,ＨＥＣＣＭ中的ＰＤＧＦ含量明显高于ＮＥＣＣＭ;ＨＥＣＣＭ能明显增强ＰＡＳＭＣ内ＤＮＡ合成,促进ＰＡＳＭＣ从Ｇｏ／Ｇ１期进入Ｓ期;当预先加入ＰＤＧＦ－Ｂ链抗体时,则会明显地抑制ＨＥＣＣＭ对ＰＡＳＭＣ的ＤＮＡ合成,阻止ＰＡＳＭＣ从Ｇｏ／Ｇ１期进入Ｓ期。结果提示,低氧时ＰＡＳＭＣ增殖与肺动脉内皮细胞分泌释放ＰＤＧＦ增加有关     

Early events in murine erythroleukemia cells induced to differentiate: Variation of the cell cycle parameters in relation to p53 accumulation

Among the early events of induced differentiation of murine erythroleukemia cells that we studied was the variations of cell distribution in the cell cycle as a function of the time of induction. Flow-cytofluorimetry measurements of DNA content and BrdU incorporation allowed for a precise determination of the variations of the cell cycle parameters. Cells underwent a transient arrest in both G1 and G2 + M between 6 to 16 h of induction. The progression of the cells through S phase seems not to be affected during this period. After this time cells escaped from G1 and reentered the S phase. We described previously [S. Khochbin et al. (1988) J. Mol. Biol. 200, 55-64], that p53 decreased continuously during the induction of MELC and remained at a steady-state level after 18 to 20 h of induction. In order to look for a possible redistribution of the protein along the cell cycle during the induction process, we measured the accumulation of the protein along the cell cycle. In noninduced cells there were four steps in the accumulation of the protein throughout the cell cycle: the amount of p53 was constant during G1 and it increased as cells progressed through S phase, which is characterized by an increased accumulation at the G1/S transition and a more moderate accumulation during progression through the rest of the S phase. A constant level in G2/M, approximately twice that obtained in G1, was achieved. There was no change in this distribution that correlated with the various modifications of the cell cycle in induced cells. It seems then, that p53 is associated neither with the progression of the cells in the S phase nor with the resumption of the DNA synthesis after the G1 block.     

Effects of 2-chloro-2'-deoxyadenosine on the cell cycle in the human leukemia EHEB cell line

To explain why 2-chloro-2'-deoxyadenosine (CdA) is unable to block DNA synthesis and cell cycle progression, and paradoxically enhances progression from G1 into S phase in the CdA-resistant leukemia EHEB cell line, we studied its metabolism and effects on proteins regulating the transition from G1 to S phase. A low deoxycytidine kinase activity and CdATP accumulation, and a lack of p21 induction despite p53 phosphorylation and accumulation may account for the inability of CdA to block the cell cycle. An alternative pathway involving pRb phosphorylation seems implicated in the CdA-induced increase in G1 to S phase progression.     

Immunodetection of retinoblastoma-related protein and its phosphorylated form in interphase and mitotic alfalfa cells

Plant retinoblastoma-related (RBR) proteins are primarily considered as key regulators of G(1)/S phase transition, with functional roles in a variety of cellular events during plant growth and organ development. Polyclonal antibody against the C-terminal region of the Arabidopsis RBR1 protein also specifically recognizes the alfalfa 115?kDa MsRBR protein, as shown by the antigen competition assay. The MsRBR protein was detected in all cell cycle phases, with a moderate increase in samples representing G(2)/M cells. Antibody against the human phospho-pRb peptide (Ser807/811) cross-reacted with the same 115?kDa MsRBR protein and with the in vitro phosphorylated MsRBR protein C-terminal fragment. Phospho-MsRBR protein was low in G(1) cells. Its amount increased upon entry into the S phase and remained high during the G(2)/M phases. Roscovitine treatment abolished the activity of alfalfa MsCDKA1;1 and MsCDKB2;1, and the phospho-MsRBR protein level was significantly decreased in the treated cells. Colchicine block increased the detected levels of both forms of MsRBR protein. Reduced levels of the MsRBR protein in cells at stationary phase or grown in hormone-free medium can be a sign of the division-dependent presence of plant RBR proteins. Immunolocalization of the phospho-MsRBR protein indicated spots of variable number and size in the labelled interphase nuclei and high signal intensity of nuclear granules in prophase. Structures similar to phospho-MsRBR proteins cannot be recognized in later mitotic phases. Based on the presented western blot and immunolocalization data, the possible involvement of RBR proteins in G(2)/M phase regulation in plant cells is discussed.     

Flow cytometry of the differentiation of Physarum polycephalum myxamoebae to cysts

Myxamoebae of Physarum polycephalum, strain Cld, were grown on agar lawns on live bacteria. Myxamoebae were harvested, fixed and stained with propidium iodide. Flow cytometry showed that, as in the case of Physarum plasmodia, there is no G1 phase during rapid exponential growth. However, an apparent G1 phase was observed at the end of exponential growth when the culture arrested with the G1 DNA content for about a day between growth and differentiation. Most myxamoebae differentiated into cysts, but some formed microplasmodia and others appeared to lose DNA. The cysts possessed the G2 phase DNA content and there was an S phase connecting the G1-arrested state with the encysted state. Encystment was blocked by hydroxyurea (HU) suggesting that DNA synthesis is essential for encystment. The natural temporary synchronization in G1 phase may provide the basis of a method for selecting mutants with a conditional block in G2 or M phases.     

Flow cytometric analysis of unbalanced control of protein accumulation and DNA synthesis in differentiating mouse myeloid leukemia cells

The protein and DNA contents of mouse myeloid leukemia M1 (clone B24) cells were determined by flow cytometry (FCM) after double fluorescent staining of the cells with fluorescein isothiocyanate and propidium iodide. FCM analysis showed that there was a linear relationship between the DNA and protein contents in logarithmically growing cells, although the protein content showed some variation. B24 cells can be induced to differentiate into macrophage-like cells by treatment with a protein inducer(s) in conditioned medium (CM) of hamster embryo cells. When the cells were treated with various concentrations of CM, cells with a 2C DNA content, G1/0 cells, increased and protein accumulated in these G1/0 cells. The increases in the number of G1/0 cells and in their protein content per cell were proportional to the concentration of CM. Serial analysis of changes in the contents of DNA and protein in differentiating B24 cells showed that DNA synthesis was suppressed by differentiation-induced block of the cell cycle at the G1/0 phase, whereas increase in the protein content was not completely suppressed by block of the cell cycle. These results suggest that unbalanced control of the DNA and protein contents of B24 cells is involved in the mechanisms of the morphological changes during differentiation into macrophages.     

DNA damage-induced inhibition of rRNA synthesis by DNA-PK and PARP-1

RNA synthesis and DNA replication cease after DNA damage. We studied RNA synthesis using an in situ run-on assay and found ribosomal RNA (rRNA) synthesis was inhibited 24 h after UV light, gamma radiation or DNA cross-linking by cisplatin in human cells. Cisplatin led to accumulation of cells in S phase. Inhibition of the DNA repair proteins DNA-dependent protein kinase (DNA-PK) or poly(ADP-ribose) polymerase 1 (PARP-1) prevented the DNA damage-induced block of rRNA synthesis. However, DNA-PK and PARP-1 inhibition did not prevent the cisplatin-induced arrest of cell cycle in S phase, nor did it induce de novo BrdU incorporation. Loss of DNA-PK function prevented activation of PARP-1 and its recruitment to chromatin in damaged cells, suggesting regulation of PARP-1 by DNA-PK within a pathway of DNA repair. From these results, we propose a sequential activation of DNA-PK and PARP-1 in cells arrested in S phase by DNA damage causes the interruption of rRNA synthesis after DNA damage.     

Induction of cellular deoxyribonucleic acid synthesis in butyrate-treated cells by simian virus 40 deoxyribonucleic acid.

Sodium butyrate (3 mM) inhibited the entry into the S phase of quiescent 3T3 cells stimulated by serum, but had no effect on the accumulation of cellular ribonucleic acid. Simian virus 40 infection or manual microinjection of cloned fragments from the simian virus 40 A gene caused quiescent 3T3 cells to enter the S phase even in the presence of butyrate. NGI cells, a line of 3T3 cells transformed by simian virus 40, grew vigorously in 3 mM butyrate. Homokaryons were formed between G1 and S-phase 3T3 cells, Butyrate inhibited the induction of deoxyribonucleic acid synthesis that usually occurs in B1 nuclei when G1 cells are fused with S-phase cells. However, when G1 3T3 cells were fused with exponentially growing NGI cells, the 3T3 nuclei were induced to enter deoxyribonucleic acid synthesis. In tsAF8 cells, a ribonucleic acid polymerase II mutant that stops in the G1 phase of the cell cycle, no temporal sequence was demonstrated between the butyrate block and the temperature-sensitive block. These results confirm previous reports that certain virally coded proteins can induce cell deoxyribonucleic acid synthesis in the absence of cellular functions that are required by serum-stimulated cells. Our interpretation of these data is that butyrate inhibited cell growth by inhibiting the expression of genes required for the G0 leads to G1 leads to S transition and that the product of the simian virus 40 A gene overrode this inhibition by providing all of the necessary functions for the entry into the S phase.     

Abrogation of growth arrest signals by human papillomavirus type 16 E7 is mediated by sequences required for transformation.

Cells arrest in the G1 or G0 phase of the cell cycle in response to a variety of negative growth signals that induce arrest by different molecular pathways. The ability of human papillomavirus (HPV) oncogenes to bypass these signals and allow cells to progress into the S phase probably contributes to the neoplastic potential of the virus. The E7 protein of HPV-16 was able to disrupt the response of epithelial cells to three different negative growth arrest signals: quiescence imposed upon suprabasal epithelial cells, G1 arrest induced by DNA damage, and inhibition of DNA synthesis caused by treatment with transforming growth factor beta. The same set of mutated E7 proteins was able to abrogate all three growth arrest signals. Mutant proteins that failed to abrogate growth arrest signals were transformation deficient and included E7 proteins that bound retinoblastoma protein in vitro. In contrast, HPV-16 E6 was able to bypass only DNA damage-induced G1 arrest, not suprabasal quiescence or transforming growth factor beta-induced arrest. The E6 and E7 proteins from the low-risk virus HPV-6 were not able to bypass any of the growth arrest signals.     

Effects of 2‐Chloro‐2′‐Deoxyadenosine on the Cell Cycle in the Human Leukemia EHEB Cell Line

To explain why 2‐chloro‐2′‐deoxyadenosine (CdA) is unable to block DNA synthesis and cell cycle progression, and paradoxically enhances progression from G1 into S phase in the CdA‐resistant leukemia EHEB cell line, we studied its metabolism and effects on proteins regulating the transition from G1 to S phase. A low deoxycytidine kinase activity and CdATP accumulation, and a lack of p21 induction despite p53 phosphorylation and accumulation may account for the inability of CdA to block the cell cycle. An alternative pathway involving pRb phosphorylation seems implicated in the CdA‐induced increase in G1 to S phase progression.