Cell proliferation kinetics of MCF-7 human mammary carcinoma cells in culture and effects of tamoxifen on exponentially growing and plateau-phase cells

MCF-7 human mammary carcinoma cells were inoculated into 150-sq cm flasks at 3 X 10(5) cells/flask, and after a lag period of about 48 hr, these cells grew exponentially for 5 days with a mean population doubling time of about 24 hr. During exponential growth, 80 to 90% of cells were in the "rapidly cycling" pool, the clonogenic fraction was 50 to 60%, and the mean percentage of cells in the G0-G1, S, and G2 + M phases of the cell cycle was 48.9 +/- 0.6% (S.E.), 39.4 +/- 0.6%, and 11.6 +/- 0.3%, respectively. These parameters changed rapidly between Days 7 and 13 when plateau phase was reached. Between Days 13 and 18, 74.8 +/- 0.7% of cells were in G0-G1, 15.3 +/- 0.4% were in S, and 9.8 +/- 0.6% were in G2 + M phase. Only about 30% of these cells were cycling rapidly, and the clonogenic fraction had fallen to less than 10%. Tamoxifen induced a dose-dependent decrease in the growth rate of exponentially growing cells, which was accompanied by a dose-dependent increase in percentage of G0-G1-phase cells, and a decline in percentage of S-phase cells. At doses greater than or equal to 10 microM, a 24-hr pulse of tamoxifen was cytotoxic to exponentially growing cells. Plateau-phase cells were less sensitive to these effects of tamoxifen. In an attempt to define the kinetic basis of the G0-G1 accumulation induced by tamoxifen, asynchronous MCF-7 cells were pretreated for 42 hr with various doses of tamoxifen, and the rate of efflux of cells from the G0-G1 phase of the cell cycle was assessed by blocking their reentry into G1 with ICRF 159. Following treatment of control cultures with ICRF 159, two populations of cells were distinguished by their rates of efflux from G0-G1 phase. The majority of cells left G0-G1 rapidly with a mean t1/2 of 2.3 hr ("rapidly cycling" cells). However, about 18% of cells had a much slower rate of exit with a mean t1/2 of about 30 hr ("slowly cycling" cells). Pretreatment with tamoxifen resulted in a dose-dependent decrease in the proportion of rapidly cycling cells and an increase in the proportion of cells with slow G1 transit times. Although this appeared to be the predominant effect, tamoxifen also decreased the rate at which the slowly cycling cells traversed G1. Simultaneous treatment with estradiol returned these parameters to control values at doses of tamoxifen less than or equal to 5 microM, partially reversed the effect of 7.5 microM tamoxifen, but was without effect on the arrest of cell cycle progression induced by 10 microM tamoxifen. It is concluded that cells accumulate in G0-G1 following tamoxifen treatment due to an increase in the proportion of slowly cycling cells at the expense of a population of rapidly cycling cells, which appear to be relatively uninfluenced by the drug.     

15-Deoxy-Δ<Superscript>12,14</Superscript>-prostaglandin J<Subscript>2</Subscript> inhibits G<Subscript>2</Subscript>-M phase progression in human breast cancer cells via the down-regulation of cyclin B1 and survivin expression

The cyclopentenone prostaglandin 15-deoxy-Δ^12,14-prostaglandin J₂ (15d-PGJ₂) exerts a growth inhibitory effect on cancer cells, and this effect is linked to the induction of apoptosis or cell cycle arrest. Induction of apoptosis by 15d-PGJ₂ is associated with the down-regulation of anti-apoptotic proteins. G₀-G₁→S phase progression is inhibited by 15d-PGJ₂ via the degradation of cyclin D1. In this study, we further investigated the mechanism by which 15d-PGJ₂ inhibits cancer cell growth by using the breast cancer cell lines MCF-7 and T-47D. Treatment with 20 μM 15d-PGJ₂ for 72 h completely blocked the growth in both cell lines. However, the proportions of apoptotic MCF-7 and T-47D cells were 21.1% and 40.9%, respectively, indicating that the induction of apoptosis did not appear to fully account for growth inhibition by 15d-PGJ₂. Cell cycle analysis using cells synchronized at the G₀-G₁ or S phase revealed that 15d-PGJ₂ blocked not only G₀-G₁→S phase progression but also G₂-M phase progression. The expression of both cyclins D1 and B1 was decreased by 15d-PGJ₂. Furthermore, 15d-PGJ₂ inhibited aurora-B kinase activity, which coincided with the down-regulation of survivin. Thus, 15d-PGJ₂ induced cell cycle arrest at the G₂-M phase via inhibition of cyclin B1 expression and aurora-B kinase activity. We conclude that survivin may be an important target for 15d-PGJ₂, and its down-regulation may lead to a decrease in aurora-B kinase activity. Naoki Tsuji substantially contributed to this work and should also be considered a first author.     

Points of action of estrogen antagonists and a calmodulin antagonist within the MCF-7 human breast cancer cell cycle

Tamoxifen and other structurally related nonsteroidal antiestrogens possess properties in addition to their estrogen antagonist activity including inhibition of both calmodulin and protein kinase C. The present studies were designed to test whether the estrogen-reversible (estrogen receptor mediated) and estrogen-irreversible effects of nonsteroidal antiestrogens on cell cycle progression in vitro were mediated at the same or different points within the cell cycle and if the estrogen-irreversible effects coincided temporally with that of a calmodulin antagonist, R24571. Initial experiments investigated the effects of ICI 164384, a pure estrogen antagonist, on proliferation kinetics in asynchronous cultures of MCF-7 human breast cancer cells. At concentrations greater than 1 nM ICI 164384 significantly reduced growth rate while at greater than or equal to 50 nM, ICI 164384 completely arrested growth after the first 24 h of exposure. Concentrations up to 5 microM failed either to cause more profound effects on growth or induce cytotoxicity. Growth inhibition was associated with a decrease in the proportion of S phase cells and an accumulation of cells in G1 phase, and was completely reversed by the simultaneous addition of equimolar estradiol. In order to identify the points of action within the cell cycle of ICI 164384, and the estrogen-reversible and estrogen-irreversible components of the nonsteroidal estrogen antagonist, hydroxyclomiphene, and the calmodulin antagonist, R24571, experiments were undertaken with MCF-7 cells synchronized by mitotic selection. The mean point of action was assessed by delaying addition of the drugs for increasing time periods following mitotic selection and using DNA flow cytometry to determine the proportion of the population affected by drug administration at a specific time within G1 phase. These studies showed that sensitivity to ICI 164384 was restricted to the early part of G1 phase and that the mean time of action was 4.9 h after the beginning of G1 for this pure estrogen antagonist. The mean times of action of the estrogen-reversible (4.1 h into G1 phase) and estrogen-irreversible (4.1 h) mechanisms of action of hydroxyclomiphene, and R24571 (4.0 h), all appeared to be within a similar time frame in early to mid G1 phase. It is concluded that ICI 164384 inhibits breast cancer cell proliferation by inducing a transition delay in G1 phase and that the point of action of this pure estrogen antagonist in early G1 phase is indistinguishable temporally from that of nonsteroidal antiestrogens and calmodulin antagonists.     

Effects of chartreusin on cell survival and cell cycle progression

Chartreusin was lethal to both L1210 and P388 cells in culture with 90% of the cells being killed after a 24-hr exposure to 1.1 and 2.6 microgram/ml, respectively. The lethality of the drug increased in direct proportion to dose and exposure time. Both L1210 and Chinese hamster ovary cells in S phase were more sensitive to the lethality of the drug than were their corresponding non-S-phase cells. L1210 cells were partially synchronized by exposing an asynchronous culture to [methyl-3H]thymidine (20 Ci/mmol) and Colcemid for 3 hr. Synchronous culture of Chinese hamster ovary cells was established by planting mitotic cells. The progression of cells through the cell cycle was studied with flow microfluorometry both in the presence of the drug and after the drug had been washed off. In the presence of chartreusin the progression of mitotic cells into G1 was not affected. The movement of G1 cells into S was slower, and the movement of G2 cells into mitosis was blocked. When the drug was removed, the G2 to M block persisted for at least 4 hr but the progression of G1 cells to S was no longer inhibited.     

Effect of medroxyprogesterone acetate on proliferation and cell cycle kinetics of human mammary carcinoma cells

The effect of medroxyprogesterone acetate (MPA) on breast cancer cell proliferation kinetics was investigated in ten human breast cell lines growing as monolayer cultures. Significant inhibition of growth occurred only in the estrogen receptor-positive, progesterone receptor-positive cell lines, T-47D, MCF-7, ZR 75-1, BT 474, and MDA-MB-361. Among these cell lines sensitivity to MPA varied widely; concentrations required for 20% inhibition of growth ranged from 0.04 nM for T-47D to greater than 100 nM for ZR 75-1 cells. Furthermore, although the most sensitive line, T-47D, had the highest level of PR, sensitivity to MPA was not correlated with PR levels among the responsive cell lines. More detailed studies were undertaken with the T-47D cell line. The growth-inhibitory response was confined to the progestins: MPA, ORG 2058, R5020, and progesterone, while androgens, estrogens, and glucocorticoids were without effect over the same concentration range (0.1-100 nM). MPA-induced growth inhibition was associated with a significant decrease in the proportion of S-phase cells with an accumulation of cells in the G0-G1 phase of the cell cycle. Cells began to accumulate in G0-G1 after 12 h of drug treatment and the effect was maximal by 24 h, i.e., maximal effects were observed during the first cell cycle following drug treatment. By contrast, significant accumulation in G0-G1 required exposure of MCF-7 cells to MPA for at least two cell cycle times, i.e., 48 h and the effect was still increasing at 96 h. Stathmokinetic studies revealed that in both cell lines accumulation in the G0-G1 phase was due to an MPA-induced increase in the G1 transit time. These data indicate that MPA and other progestins have direct growth inhibitory effects on estrogen receptor-positive and progesterone receptor-positive human breast cancer cells in vitro and these effects can be accounted for by a decrease in the rate at which cells traverse the G1 phase of the cell cycle.     

Cell cycle effects of CC-1065

CC-1065 is the most potent antitumor agent tested in our laboratory. It is lethal to B16 and CHO cells and to a variety of human tumors in the clonogenic assay at 1 ng/ml and is effective against L1210 leukemia and B16 melanoma in vivo at 1 to 50 micrograms/kg. CC-1065 inhibits DNA synthesis and binds to DNA in a nonintercalative manner in the minor groove. We report here the kinetics of inhibition of DNA synthesis and of cell progression and the phase-specific toxicity of the drug. To determine phase-specific toxicity, we started synchronous CHO cultures from mitotic cells harvested after Colcemid pretreatment. These cultures showed that mitotic cells were the most sensitive, and sensitivity decreased as the cells progressed through G1 to S and G2. Experiments with B16 and CHO mitotic cells harvested without Colcemid pretreatment also showed that mitotic cells were more sensitive than G1/S-phase cells. Cell progression studies showed that CC-1065 did not affect progression from mitosis to G1 or from G1 to S. Cells progressed slowly through S at low levels (1 ng/ml) of the drug but were blocked in S at 5 ng/ml. Cell progression from G2 to M was blocked by CC-1065. DNA synthesis in B16 cells was measured at different times after 2-hr exposure to CC-1065. The percentage of inhibition of DNA synthesis was minimum at 4 hr and maximum at 19 hr after drug exposure. Since B16 cell progression studies showed a marked change in percentage of S-phase cells during this time, the DNA synthesis rate was recalculated as cpm/S-phase cell. After this correction (i.e., expressing DNA synthesis as cpm/S-phase cell), the percentage of inhibition of DNA synthesis was minimum at 0 hr and gradually increased to maximum inhibition at 19 hr without the decrease seen previously at 4 hr.     

Cell cycle regulation of menin expression.

The multiple endocrine neoplasia type 1 gene product, menin, interacts with Jun D. The physiological role of menin in cell cycle control and the manner in which its inactivation contributes to tumorigenesis remain unknown. In the present study, the expression of menin was examined at various cell cycle stages in GH4C1 cells, a rat pituitary cell line. Cells synchronized at the G1-S-phase boundary expressed menin at a lower level than G0-G1-synchronized cells. The expression of menin increased as the cells entered S phase, at which time Jun D expression also increased. In contrast, cells synchronized at the G2-M phase expressed lower levels of menin. At G0-G1, G1-S, and G2-M phases of the cell cycle, menin was found predominantly in the nucleus. In summary, we show that in pituitary cells, menin is a nuclear protein whose expression is cell-cycle regulated. The data suggest that menin has an important role in cell growth regulation.     

Interleukin-1 alpha differentially synchronizes estrogen-dependent and estrogen-independent human breast cancer cells in the G0/G1 phase of the cell cycle.

Direct in vitro effects of IL-1 alpha on cell cycle progression of the estrogen-responsive, MCF-7, and estrogen-unresponsive, MDA-231, human breast cancer cells were investigated by flow cytometry. IL-1 alpha, at nanomolar concentrations, caused the synchronization of MCF-7, but not MDA-231, cells in the G0/G1 phase of the cell cycle. The S phase of IL-1 treated MCF-7 cells was correspondingly decreased. The IL-1 induced synchronization of MCF-7 cells was observed in the dose range of 10(-11) M to 10(-7) M and was seen as early as 6 h after the start of treatment. Furthermore, these effects were shown to be sensitive to the weak estrogen, phenol red, since the IL-1-induced shifts in G0/G1 and S phases were markedly blunted in its presence. In cell proliferation experiments, the IL-1-induced synchronization of MCF-7 cells increased the cytotoxic efficacy of the chemotherapeutic drug, 5-fluorodeoxyuracil. These data demonstrate that IL-1 by arresting the estrogen-responsive human breast cancer cells, MCF-7, in the G0/G1-phase of the cell cycle can not only directly inhibit the growth of MCF-7 cells, but also increase the efficacy of FUDR.     

Cell cycle expression of steroid receptors determined by image analysis on human breast cancer cell line: A hypothesis on the effects of antiestrogens

Tamoxifen is the widespread anti-hormonal compound used for the treatment of human breast cancer. It is admitted that its effects are mediated via estrogen receptors (ER) but the molecular basis of its activity has yet to be clearly defined. In this work, we have developed a new image cytometry procedure in order to clarify the interactions between steroid receptors and tamoxifen at the cell cycle kinetic level. On untreated cells, an increase of ER level and a decrease of progesterone receptor (PR) level during the G0/G1 phase were demonstrated. Then, the ER and PR levels fell during the S-phase until the beginning of G2/M phase, where an increase was observed, especially for PR. These results suggest that ER is synthesized preferentially during the G0/G1 transition and PR during the S/G2 transition. After short-term tamoxifen treatment an augmentation of ER level was observed which was not dose-dependent, suggesting an increase in receptor translation rather than an augmentation of ER synthesis. PR level declined in the majority of the population leading to a selection of a subset of proliferating PR negative cells after treatment. These data demonstrate that the synthesis of steroid receptors is linked with the progression of cells through the cell cycle and indicate that tamoxifen blocks MCF-7 cells in G1 via its interactions with ER. Our multifluorescence imaging procedure appears to provide a rapid and quantitative approach which is useful for investigating alterations in steroid receptors after endocrine treatment.     

Synergistic interactions between tamoxifen and trastuzumab (Herceptin).

PURPOSE: HER-2/neu and estrogen receptor (ER) are critical in the biology of breast carcinoma, and both are validated therapeutic targets. Extensive interactions between the signaling pathways of these receptors have been demonstrated. This suggests that targeting both receptors simultaneously may have a dramatic effect on the biology of breast cancer. This hypothesis was tested in cell culture experiments. EXPERIMENTAL DESIGN: ER-positive, HER-2/neu-overexpressing BT-474 human breast carcinoma cells were cultured in the presence of the anti-HER-2/neu therapeutic antibody trastuzumab (Herceptin), the antiestrogen tamoxifen, or both. The effects on cell growth, cell cycle distribution, clonogenicity, survival, and the level and activity of HER-2/neu were examined. RESULTS: The combination of tamoxifen and Herceptin resulted in synergistic growth inhibition and enhancement of cell accumulation in the G(0)-G(1) phase of the cell cycle, with a decrease in cells in S phase. Clonogenicity was inhibited in the presence of each drug and more so by the combination, although prior exposure to drugs did not affect subsequent clonogenicity in drug-free media, and neither drug nor the combination induced apoptosis. Herceptin, but not tamoxifen, inhibited signaling by HER-2/neu. CONCLUSIONS: The combination of tamoxifen and Herceptin is formally demonstrated to result in synergistic growth inhibition and enhancement of G(0)-G(1) cell cycle accumulation. In vitro, the individual drugs or combination produces a cytostatic effect. These results suggest that combined inhibition of ER and HER-2/neu signaling may represent a powerful approach to the treatment of breast cancer.     

Effect of ACNU, a water-soluble nitrosourea derivative, on survival and cell progression of cultured HeLa S3 cells

Effects of a water-soluble nitrosourea derivative, 1-(4-amino-2-methylpyrimidin-5-yl) methyl-3-(2-chloroethyl)-3-nitrosourea hydrochloride [ACNU]. on survival and cell progression of HaLe S3 cells was investigated. The survival of exponentially growing cells exposed to increasing concentrations of the drug was characterized by a threshold-type survival curve (D0 = 7.0 micrograms/ml X 1 hr, Dq = 3.5 micrograms/ml X 1 hr). ACNU exerted its main killing effect on cells in G1 and G2 + M phases, whereas cells in S phase were resistant to the drug. Changes in survival response as a function of cell cycle were mainly dependent upon the extent of the exponential slope of the survival curve. Cell progression effects were examined by using a low concentration of ACNU in which 80% of treated cells could survive. Cells in G1 and early S phases at the time of treatment were not prevented from entering S phase but prolonged in duration of S phase followed by a marked delay in progression through G2 phase. However, such a delay in cell progression time was reduced in cells treated in mid S phase as compared with G1 and early S phases. Cells treated in late S and G2 phases could normally progress into mitosis.     

Comparative studies of steroidogenesis inhibitors (econazole, ketoconazole) on human breast cancer MCF-7 cell proliferation by growth experiments, thymidine incorporation and flow cytometric DNA analysis.

The effects of aminoglutethimide, econazole and ketoconazole on human breast cancer cells in culture were compared with those of tamoxifen using four methods (growth experiments, thymidine incorporation, monoparameter and bivariate DNA content flow cytometry analysis). Aminoglutethimide (1 nM-10 microM) had no effect on cell proliferation after 8 days of treatment and did not decrease thymidine tritiated incorporation during logarithmic phase. Even at 20 microM, similar results were obtained with flow cytometry. Econazole and ketoconazole (1 nM-1 microM) decreased MCF-7 cell proliferation in a time- and dose-dependent fashion. They also decreased tritiated thymidine incorporation. By using flow cytometry and a monoclonal antibody against bromodeoxyuridine, we showed an accumulation of MCF-7 cells treated by imidazoles derivatives in G0-G1 phase of the cell cycle.     

组蛋白去乙酰化酶抑制剂辛二酰-双羟肟酸对乳腺癌细胞增殖的影响

背景与目的:目前乳腺癌发病率仍居首位,是严重威胁女性健康的主要肿瘤之一。组蛋白去乙酰化酶抑制剂辛二酰双羟肟酸(suberic bishydroxamate,suberoyl bishydroxamic acid,SBHA)能够抑制组蛋白去乙酰化酶(histone deacetylase,HDAC)中的HDAC1和HDAC3的活性,选择性抑制某些肿瘤的生长而对正常细胞无不良反应。本实验旨在研究SBHA对人乳腺癌细胞增殖及周期的影响。方法:将不同浓度的SBHA以不同时间作用于乳腺癌MCF-7及MDA-MB-231细胞,用WST-8法检测其对细胞增殖能力的影响;用相差显微镜观察药物对细胞形态学变化;用流式细胞仪分析细胞周期。结果:SBHA呈时间和剂量依赖性抑制乳腺癌细胞增殖,使细胞形态发生明显变化,明显使G0～G1期细胞比例增高,S期细胞比例降低,与对照组比较差异有统计学意义(P>0.05)。结论:SBHA具有抑制人乳腺癌细胞增殖作用,使细胞阻滞在G0～G1期。     

Differential sensitivity of human breast cancer cell lines to the growth-inhibitory effects of tamoxifen

In eight estrogen receptor (ER)-positive breast cancer cell lines (including three sublines of MCF-7) and five ER-negative breast lines, the action of the nonsteroidal antiestrogen, tamoxifen, was studied, and the concentrations of ER and antiestrogen binding site were measured. The concentration of antiestrogen binding site was significantly [P less than 0.005] greater in ER-positive cells [236,600 +/- 29,900 (SE) sites/cell] than in ER-negative cell lines [66,600 +/- 16,800 sites/cell]. In ER-positive cell lines, a cell cycle phase-specific growth-inhibitory effect, 20% inhibitory dose less than 0.1 to 1.0 microM, was seen which was shown for some representative cell lines to be estrogen reversible. Within this group of cell lines, the degree of tamoxifen-induced inhibition of growth correlated with control population doubling time, but not ER or antiestrogen binding site concentration. The changes in cell cycle kinetic parameters characteristic of all ER-positive lines were a decrease in percentage of S-phase cells and a corresponding increase in percentage of G0-G1 cells. In all cell lines, 5 to 12.5 microM tamoxifen caused cytotoxicity, and this was shown to be estrogen-irreversible in 3 representative cell lines; moreover, estradiol synergistically enhanced the cytotoxic effects of tamoxifen under some experimental conditions. The cell cycle effects of tamoxifen in three ER-negative cell lines (Hs0578T, MDA-MB-231, MDA-MB-330) were decreased proportions of G0-G1 cells with an increase in percentages of S and G2+M cells. These results implied that the mechanism of tamoxifen cytotoxicity may differ in ER-positive and ER-negative breast cancer cells. However, although the ER-negative BT-20 line was much less sensitive to tamoxifen than were the ER-positive cells, growth inhibition and cytotoxicity in this line were associated with a slight decrease in percentage of S-phase cells. These results confirm that ER-positive breast cancer cells are more sensitive (4- to greater than 75-fold) than ER-negative breast cells to the growth-inhibitory effects of tamoxifen and demonstrate that, in all ER-positive cells, growth inhibition and cytotoxicity are accompanied by characteristic changes in cell cycle kinetic parameters. In contrast, different mechanisms may be involved in the effects of tamoxifen on different ER-negative cell lines.     

Redox regulation of the G1 to S phase transition in the mouse embryo fibroblast cell cycle

The hypothesis that intracellular oxidation/reduction (redox) reactions regulate the G(0)-G(1) to S-phase transition in the mouse embryonic fibroblast cell cycle was investigated. Intracellular redox state was modulated with a thiol-antioxidant, N-acetyl-L-cysteine (NAC), and cell cycle progression was measured using BrdUrd pulse-chase and flow cytometric analysis. Treatment with NAC for 12 h resulted in an approximately 6-fold increase in intracellular low-molecular-weight thiols and a decrease in the MFI of an oxidation-sensitive probe, dihydrofluorescein diacetate, indicating a shift in the intracellular redox state toward a more reducing environment. NAC-induced alterations in redox state caused selective delays in progression from G(0)-G(1) to S phase in serum-starved cells that were serum stimulated to reenter the cell cycle as well as to inhibit progression from G(1) to S phase in asynchronous cultures with no significant alterations in S phase, and G(2)+M transits. NAC treatment also showed a 70% decrease in cyclin D1 protein levels and a 3-4-fold increase in p27 protein levels, which correlated with decreased retinoblastoma protein phosphorylation. Cells released from the NAC treatment showed a transient increase in dihydrofluorescein fluorescence and oxidized glutathione content between 0 and 8 h after release, indicating a shift in intracellular redox state to a more oxidizing environment. These changes in redox state were followed by an increase in cyclin D1, a decrease in p27, retinoblastoma protein hyperphosphorylation and subsequent entry into S phase by 8-12 h after the removal of NAC. These results support the hypothesis that a redox cycle within the mammalian cell cycle might provide a mechanistic link between the metabolic processes early in G(1) and the activation of G(1)-regulatory proteins in preparation for the entry of cells into S phase.     

Effects of the antioestrogen tamoxifen on the cell cycle kinetics of the human breast cancer cell line, MCF-7

The effect of 10(-6) M tamoxifen on MCF-7 cells adapted to growth in 0.5% foetal calf serum has been studied. The growth inhibitory effect of this tamoxifen concentration was abolished by simultaneous addition of 10(-8) M oestradiol, indicating that tamoxifen may exert its effect via binding to the oestrogen receptor. Flow cytometric cell cycle analysis of tamoxifen-treated cultures showed an increase in the proportion of cells in the G1 phase of the cell cycle. By exposing the cells to BUdR before flow cytometry the growth fraction was determined and found to be dramatically decreased in tamoxifen-treated cultures. Cells were not only arrested in the G1 phase but also in the G2 phase of the cell cycle. A few colonies of MCF-7 cells were resistant to 10 days treatment with 10(-6) M tamoxifen.     

Neocarzinostatin-induced DNA strand scission and subsequent cell cycle traverse in HeLa S3 cells

HeLa cells were synchronized at the G1-S boundary by double thymidine block and treated for 1 hr with varying concentrations of the antibiotic anticancer protein neocarzinostatin (NCS). Cells were then released from the block and allowed to resume their cycle. Aliquots were removed at various times in order to monitor cell cycle progression and to assess repair of DNA strand breaks. Dose-dependent DNA strand breakage occurred at all concentrations of NCS tested down to 0.05 microgram/ml. Flow cytometry revealed that NCS-treated cells were delayed in entering S phase and that once in S phase their rate of progression through it was retarded significantly. At all concentrations of NCS tested, the majority of cells did not enter G2 by 12 hr. Untreated cells, on the other hand, completed mitosis by this time. NCS-treated cells had little ability to repair DNA breaks. There appeared to be a correlation between the initial number of NCS-induced DNA breaks and the delayed entry into the S phase but little correlation between the lack of strand scission repair and the retarded progress through S phase.     

Cell cycle synchronization of FRTL5 cells. A physiological model system

We describe a "physiological" cell cycle synchronization model system. FRTL5 cells, TSH-dependent for proliferation, were starved from TSH. The cell cycle phases and the expression of markers associated to different cycle phases were evaluated. TSH starvation blocks proliferation without provoking death and induces virtually all the cells to accumulate in G0/G1 phase. TSH readdition allows 30% of these cells to enter the S phase. DNA topoisomerase II 170-kDa isoform is not expressed in G0/G1 synchronized cells while it is expressed in logarithmic growing cells. The 180-kDa isoform is not expressed in G0/G1 synchronized cells while it is expressed in 20% of logarithmic growing cells regardless of the cycle phase. c-myc mRNA is not expressed in G0/G1 synchronized cells while it is detectable upon TSH readdition. This system provides a tool for the analysis of events associated with the G0/G1 phase and the transition from G0/G1 to S phase.