Flow cytometric BrdUrd-pulse-chase study of X-ray-induced alterations in cell cycle progression

To better understand how the flow cytometric bromodeoxyuridine (BrdUrd)-pulse-chase method detects perturbed cell kinetics we applied it to measure cell cycle progression delays following exposure to ionizing radiation. Since this method will allow both the use of asynchronous cell populations and the determination of the alterations in cell cycle progression specific to cells irradiated in given cell cycle phases, it has a significant advantage over laborious synchronization methods. Exponentially growing Chinese hamster ovary (CHO) K1 cells were irradiated with graded doses of X-rays and pulse-labelled with BrdUrd immediately thereafter. Cells were subcultured in a BrdUrd-free medium for various time intervals and prepared for flow cytometric analysis. Of five flow cytometric parameters examined, only those that involved cell transit through G₂, i.e. the fraction of BrdUrd-negative G₂ cells and the fraction of BrdUrd-positive cells that had not divided, showed radiation dose-dependent delays. The magnitude of the effects indicates that the cells irradiated in G₂ and in S are equally delayed. S phase transit of cells irradiated in S or in G₁ did not appear to be affected. There were apparent changes in flow of cells out of G₁, which could be explained by the delayed entry of G₂ cells into the compartment because of G₂ arrest. Thus, in asynchronous cells the method was able to detect G₂ delay in those cells irradiated in S and G₂ phases and demonstrate the absence of cell-cycle delays in other phases.     

Cell cycle suspension: A novel process lurking in G2 arrest

Cell cycle checkpoint is a self-protective mechanism for cells to monitor genome integrity and ensure the high-fidelity transmission of genetic information to daughter cells. Insufficient function of cell cycle checkpoints has been demonstrated to partially account for tumor initiation, promotion and progression. In the ten melanoma cell lines that we tested in preliminary experiments, two human uveal melanoma cell lines, 92-1 and OCM-1, were found to be significantly different in terms of radiosensitivity but similar in DNA repair ability. Evident G₂ arrest was induced in both cell types and the maximum was reached at 16 h after irradiation regardless of X-rays or high-LET carbon beams. OCM-1 cells overrode the G₂ arrest and reentered the cell cycle right after reaching the maximum, whereas 92-1 could not. Upon 10 Gy of radiation, the cell cycle of 92-1 was suspended and remained unchanged for up to 5 d. The cell cycle suspension is a unique process lurking in G₂ arrest and related to cellular radiosensitivity. Its induction is dose-dependent and there is a dose threshold for it. The degradation of Cyclin B1 has been found related to the cell cycle suspension though, the mechanism of cell cycle suspension is still under investigation. Basing on our knowledge, this is the first report on cell cycle suspension and we present here a de novo mechanism to cellular radiosensitivity. Further clarification of the mechanism underlying cell cycle suspension is believed to be of significance in tumor radiosensitization or even direct tumor control.     

Molecular mechanisms involved in the production of cromosomal aberrations II. Utilization of neurospora endonuclease for the study of aberration production by X-rays in G1 and G2 stages of the cell cycle

Chinese hamster ovary cells (CHO) were X-irradiated in G₁ and G₂ stages of the cell cycle and subsequently Neurospora endonuclease (NE) (E.C.3.1.4), an enzyme which is specific in cleaving single-stranded DNA, was introduced into the cells, after making the cells permeable by treatment with inactivated Sendai virus. With this treatment all classes of X-ray-induced chromatid aberrations increased in G₂ cells, whereas in G₁ cells an increase in cromosome type of aberrations was found, associated with a profound induction of chromatid type of aberrations as well. Duration of the availability of single-strand gaps for the action of NE has been studied in G₂ cells following X-irradiation and the influence of different parts of the G₂ stage on the type and frequencies of chromatid aberrations was discerned. While the increase in chromosome type of aberrations by NE in X-irradiated G₁ cells has been interpreted as due to the conversion of DNA single-strand breaks or gaps to double-strand breaks by NE, the induction of chromatid aberrations in G₁ has been assumed to be due to conversion of some of the damaged bases strand breaks by NE. Biochemical evidence is presented for the conversion by NE of DNA single-strand breaks induced by X-rays into double-strand breaks using neutral sucrose gradient centrifugation.     

Cell-cycle dependency of radiosensitivity and mutagenesis in fertilized egg cells of rice,Oryza sativa L.

Summary In order to examine changes in survival and mutation rates during a cell cycle in higher plant, fertilized egg cells of rice were irradiated with X-rays at 2 h intervals for the first 36 h after pollination, i.e., at different phases of the first and second cell cycles. The most sensitive phase in lethality was late G₁ to early S, followed by late G₂ to M, which were more sensitive than the other phases. In both M₁ and M₂ generations, sterile plants appeared most frequently when fertilized egg cells were irradiated at G₂ and M phases. Different kinds of mutated characters gave rise to the respective maximum mutation rates at different phases of a cell cycle: namely, albino and viridis were efficiently induced at early G₁, xantha at early S, short-culm mutant at mid G₂, heading-date mutant at M to early G₁. The present study suggests the possibility that the differential mutation spectrums concerning agronomic traits are obtained by selecting the time of irradiation after pollination.     

Analyses of differential sensitivities of synchronized HeLa S3 cells to radiations and chemical carcinogens during the cell cycle: Part V. Radiation- and chemical carcinogen-induced mutagenesis

8-Azaguanine (8AG)-resistant mutations induced by X-rays, ultraviolet radiation (UV) and a chemical carcinogen, 4-hydroxyaminoquinoline 1-oxide (4-HAQO) were examined during the cell cycle of synchronized HeLa S3 cells. Mutants induced by 400 R of X-rays occurred in a higher frequency in the X-ray sensitive G₁-S boundary phase than in the X-ray-resistant G₂, S and early g₂ phases. 8AG-resistant mutants induced by treatment with 10^?5 M 4-HAQO for 20 min appeared in a higher frequency in the early to middle S phases than in the other phases. In the case of UV, however, we found no significant difference in the induced mutation frequencies the cell cyle, because the mutation frequencies induced by the UV doses (0–20 Jm²) used were too low for detection of the difference. These results suggest that there is a close correlation between the critical damage induced in DNA molecule(s) at the DNA-synthetic phase in the cell cycle and mutagenesis, because mitotic cells have a low mutability in spite of their high radio-sensitivity.     

Analyses of differential sensitivities of synchronized HeLa S3 cells to radiations and chemical carcinogens during the cell cycle Part IV. X-rays

Radiation-induction and rejoining of single-strand breaks (SSBs) in the DNA of synchronized HeLa S3 cells were investigated by alkaline sucrose density gradients. We could not find any significant differences in the extent of SSBs induced in cellular DNA and in the extent of their rejoining throughout the cell cycle, including mitosis. The cyclic variation curve of the content of non-protein sylfhydryls (NPSH) during the cell cycle is similar to that of X-ray survivals except in mitosis, although there was no close correlation between the content of apparent total sulfhydryls (APSH) and X-ray survivals.Radiation-induced mutants resistant to 8-azaguanine (8AG) occured in higher frequency in the radio-sensitive G₁S boundary phase thanin the radio-resistant G₁, S and early G₂ phases. Further, the pre-irradiation treatment with 50 mM cysteamine prevented reproductive death and induction of 8AG-resistant mutants by X-rays throughout the cell cycle. These findings seem to indicate that there is a close correlation between the extent of lethal radiation damage to the cells and their mutability, and that sulfhydryls may play an important role as a factor governing cellular radio-sensitivity.     

Reduced inhibition of DNA synthesis and G2 arrest during the cell cycle of resistant HeLa cells in response tocis-diamminedichloroplatinum

The influence of cisplatin, an anticancer agent, on DNA synthesis and cell cycle progression of a cisplatin-resistant cell line was investigated. Cell cycle analysis using flow cytometry showed that cytotoxic concentrations of cisplatin caused a transient inhibition of parental HeLa cells at S phase, followed by accumulation at G₂ phase. In contrast, the resistant cells progressed through the cell cycle without being affected by the same treatment. However, cell cycle distributions were the same in the resistant and the parental cells at IC₅₀, the drug concentration inhibiting cell growth by 50%. Studies using a [³H]thymidine incorporation technique also demonstrated a transient inhibition of DNA synthesis in HeLa cells by cisplatin; such inhibition was greatly reduced in the resistant cells. These data argue for the hypothesis that the inhibition of DNA synthesis is important in determining cisplatin-induced cytotoxicity. In addition, the accumulation of cells at G₀/G₁ by serum starvation was not effective in the resistant cells compared to the parental cells, suggesting that the control of cell cycle exiting is also altered in the resistant cells. Taken together, these results support the notion that alterations in cell cycle control, in particular G₂ arrest, are important in determining the sensitivity or resistance of mammalian cells to cisplatin and may have a role in clinical protocols.     

L-Canavanine as a radiosensitization agent for human pancreatic cancer cells

This study evaluated the in vitro effect of L-canavanine on cell cycle progression in the two human pancreatic cancer cells lines PANC-1 and MIA PaCa-2. After 72 h of exposure to L-canavanine, the percentage of cells in the radiosensitive G₂/M phase of the cell cycle increased 6-fold in PANC-1 cells and 4-fold in MIA PaCa-2 cells, when compared to untreated cells. The capacity of L-canavanine to redistribute cells into the G₂/M phase of the cell cycle was both concentration- and time-dependent. Since many drugs that cause cells to accumulate in the G₂/M phase of the cell cycle are effective radiosensitization agents, the potential of L-canavanine to synergistically enhance the effects of ionizing radiation also was evaluated. The interaction between these treatment modalities was quantified using the median-effect equation and combination index analysis. L-Canavanine was found to be synergistic with radiation when either PANC-1 or MIA PaCa-2 cells were exposed to L-canavanine for 72 h prior to irradiation. These results suggest that L-canavanine in combination with radiation may have clinical potential in the treatment of pancreatic cancer.     

Outcome of treatment of human HeLa cervical cancer cells with roscovitine strongly depends on the dosage and cell cycle status prior to the treatment

Exposure of asynchronously growing human HeLa cervical carcinoma cells to roscovitine (ROSC), a selective cyclin‐dependent kinases (CDKs) inhibitor, arrests their progression at the transition between G₂/M and/or induces apoptosis. The outcome depends on the ROSC concentration. At higher dose ROSC represses HPV‐encoded E7 oncoprotein and initiates caspase‐dependent apoptosis. Inhibition of the site‐specific phosphorylation of survivin and Bad, occurring at high‐dose ROSC treatment, precedes the onset of apoptosis and seems to be a prerequisite for cell death. Considering the fact that in HeLa cells the G₁/S restriction checkpoint is abolished by E7, we addressed the question whether the inhibition of CDKs by pharmacological inhibitors in synchronized cells would be able to block the cell‐cycle in G₁ phase. For this purpose, we attempted to synchronize cells by serum withdrawal or by blocking of the mitotic apparatus using nocodazole. Unlike human MCF‐7 cells, HeLa cells do not undergo G₁ block after serum starvation, but respond with a slight increase of the ratio of G₁ population. Exposure of G₁‐enriched HeLa cells to ROSC after re‐feeding does not block their cell‐cycle progression at G₁‐phase, but increases the ratio of S‐ and G₂‐phase, thereby mimicking the effect on asynchronously growing cells. A quite different impact is observed after treatment of HeLa cells released from mitotic block. ROSC prevents their cell cycle progression and cells transiently accumulate in G₁‐phase. These results show that inhibition of CDKs by ROSC in cells lacking the G₁/S restriction checkpoint has different outcomes depending on the cell‐cycle status prior to the onset of treatment. J. Cell. Biochem. 106: 937–955, 2009. © 2009 Wiley‐Liss, Inc.     

cAMP and PMA enhance the effects of IGF-I in the proliferation of endometrial adenocarcinoma cell line HEC-1-A by acting at the G1 phase of the cell cycle

The present study was undertaken to determine whether endometrial cancer cell line HEC-1-A differ from nontransformed cells, in that the cAMP and protein kinase C pathways may enhance IGF-I effects in mitogenesis by acting at the G₁ phase of the cell cycle instead of G₀. Immunofluorescence staining of HEC-1-A cells using the proliferating cell nuclear antigen (PCNA) monoclonal antibody and flow cytometric analysis determined that HEC-1-A cells do not enter the G₀ phase of the cell cycle when incubated in a serum-free medium. Approximately 51% of the cells were in G₁, 12% were in S and 37% in G₂ phase of the cell cycle prior to treatment. Forskolin and phorbol-12-myristate 13-acetate (PMA) were used to stimulate cAMP production and protein kinase C activity, respectively. IGF-I, forskolin and PMA each increased (P <0.01) [³H]-thymidine incorporation in a dose and time dependent manner. The interaction of forskolin and PMA with IGF-I was then determined. Cells preincubated with forskolin or PMA followed by incubation with IFG-I incorporated significantly more (P <0.01) [³H]-thymidine into DNA than controls or any treatment alone. It is concluded that forskolin and, to a lesser extent, PMA exert their effect at the G₁ phase of the cycle to enhance IGF-I effects in cell proliferation.     

The human immunodeficiency virus type 1 Vpr protein and its carboxy-terminally truncated form induce apoptosis in tumor cells

The human immunodeficiency virus type 1 (HIV-1) accessory protein Vpr induces apoptosis after cell cycle arrest at the G₂ phase in primate cells. We have reported previously that C81, a carboxy-terminally truncated form of Vpr, interferes with cell proliferation and results in apoptosis without G₂ arrest. Here, we investigated whether this property of Vpr and C81 could be exploited for use as a potential anticancer agent. First, we demonstrated that C81 induced G₁ arrest and apoptosis in all tumor cells tested. In contrast, Vpr resulted in G₂ arrest and apoptosis in HeLa and 293 T cells. Vpr also suppressed the damaged-DNA-specific binding protein 1 (DDB1) in HepG2 cells, thereby inducing apoptosis without G₂ arrest. G₂ arrest was restored when DDB1 was overexpressed in cells that also expressed Vpr. Surprisingly, C81 induced G₂ arrest when DDB1 was overexpressed in HepG2 cells, but not in HeLa or 293 T cells. Thus, the induction of Vpr- and C81-mediated cell cycle arrest appears to depend on the cell type, whereas apoptosis was observed in all tumor cells tested. Overall, Vpr and C81 have potential as novel therapeutic agents for treatment of cancer.     

The induction of chromosomal damage and cell killing in mouse spermatogonial stem cells following combined treatments with hydroxyurea, 3-aminobenzamide and X-rays

To analyze in more detail the relation between the sensitivity of spermatogonial stem cells to killing and the induction of genetic damage, mature male mice received combined treatments with hydroxyurea (HU), 3-aminobenzamide (3-AB) and X-rays. Stem cell killing was determined using the repopulation index method and translocations were studied via spermatocyte analysis. HU was administered at 16 or at 48 h before further treatment in order to create stem cell populations with different sensitivities in whic the translocation induction and stem cell killing could be studied and compared. The sensitivities for cell death and genetic damage appeared to be strongly correlated: at 16 h after HU significantly higher values were found than at 48 h or in controls without HU pretreatment.By using 3-AB in the treatment schedules we were able to investigate whether the sensitization of stem cells towards cell death and genetic damage is the outcome of a radiation- or drug-induced G₁ delay. The effect of 3-AB was most pronounced at 16 h after HU. This confirms that at this interval a large fraction of stem cells is in G₁. Our data therefore indicate that all treatments that induce an enrichment of G₁ cells also result in a sensitization of stem cells to cell killing or the induction of mutagenic damage.     

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.     

Exposure to hyperbaric oxygen induces cell cycle perturbation in prostate cancer cells

Summary Cell cycle synchronization of tumor cells by exposure to hyperbaric oxygenation (HBO) may increase the efficacy of chemotherapy or radiation by placing cells into a chemosensitive portion of the cycle. The purpose of the current study was to examine oxygen pressure-dependent relationships with respect to the cell cycle in prostate tumor cells in vitro. LNCaP cells were grown in an incubator at 21% O₂ and then exposed to 100% oxygen at pressures up to 6 atmospheres (atm) for 1.5 h. Cells were then returned to the incubator and evaluated for DNA content by propidium iodide and new DNA synthesis with a pulse-chase experiment. Cell cycle effects were evaluated by flow cytometry. Exposure to HBO increased the percentage of cells synthesizing new DNA in a dose-dependent fashion: 0 atm, 44%; 6 atm, 65%. Cells that synthesize new DNA accumulate in G₂/M as a function of partial pressure of oxygen. These results suggest that HBO induces cells to enter the cell cycle and accumulate in G₂/M. Cell cycle synchronization and entry of senescent cells into the cell cycle suggest that HBO may be a useful adjuvant to chemotherapy or radiation in the treatment of prostate cancer. There are two potential mechanisms of action that may make HBO efficacious in the treatment of prostate cancer. HBO may potentiate cancer chemotherapeutic agents that cause damage to DNA during DNA synthesis or HBO may inhibit cell division causing accumulation in G₂/M.     

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.     

Investigations on the cell cycle of haploid and diploid tissue cultures of Datura innoxia Mill. and its synchronization

Using a ¹⁴C/³H double-labelling technique, the influence of kinetic on the length of the cell cycle of meristematic cells in haploid and diploid callus cultures of Datura innoxia was determined. The total length of the cell cycle of haploid cells as compared to that of diploid cells was reduced by 2.3 h (-kinetin) or 1.4 h (+kinetin). Furthermore, the addition of kinetin to the nutrient solution also reduces cell cycle duration at both ploidy levels. For synchronization of the cell cycle, a fluorodesoxyuridine/thymidine system was successfully employed. Apparently, the reduction of total cell cycle duration of cycling cells due to treatment with kinetin occurred at the expense of the G₁phase. Nevertheless, kinetin seems to exert an influence on the transition of cells from the G₂ into the M phase as well.Abbreviations FUdR fluorodeoxyuridine - HU hydroxyurea - IAA nidole acetic acid     

Reversible accumulation of plant suspension cell cultures in g(1) phase and subsequent synchronous traverse of the cell cycle

The induction of DNA synthesis in Datura innoxia Mill. cell cultures was determined by flow cytometry. A large fraction of the total population of cells traversed the cell cycle in synchrony when exposed to fresh medium. One hour after transfer to fresh medium, 37% of the cells were found in the process of DNA synthesis. After 24 hours of culture, 66% of the cells had accumulated in G₂ phase, and underwent cell division simultaneously. Only 10% of the cells remained in G₀ or G₁. Transfer of cells into a medium, 80% (v/v) of which was conditioned by a sister culture for 2 days, was adequate to inhibit this simultaneous traverse of the cell cycle. A large proportion of dividing cells could be arrested at the G₀ + G₁/S boundary by exposure to 10 millimolar hydroxyurea (HU) for 12 to 24 hours. Inhibition of DNA synthesis by HU was reversible, and when resuspended into fresh culture medium synchronized cells resumed the cell cycle. Consequently, a large fraction of the cell population could be obtained in the G₂ phase. However, reversal of G₁ arrested cells was not complete and a fraction of cells did not initiate DNA synthesis. Seventy-four percent of the cells simultaneously reached 4C DNA content whereas the frequency of cells which remained in G₀ + G₁ phase was approximately 17%. Incorporation of radioactive precursors into DNA and proteins identified a population of nondividing cells which represents the fraction of cells in G₀. The frequency of cells entering G₀ was 11% at each generation. Our results indicate that almost 100% of the population of dividing cells synchronously traversed the cell cycle following suspension in fresh medium.     

Progressive Increase In Polyamine Levels In 9l Cells in vitro During the Cell Cycle: Comparison Between Cells Isolated By Centrifugal Elutriation and Cells Grown In Synchrony

Centrifugal elutriation was used to separate 9L rat brain tumour cells into fractions enriched in the G₁, S, or G₂/M phases of the cell cycle. Cells enriched in early G₁, phase were recultured, grown in synchrony, and harvested periodically for analysis of their DNA distribution and polyamine content. Mathematical analysis of the DNA distributions indicated that excellent synchrony was obtained with low dissersion throughout the cell cycle. Polyamine accumulation began at the time of seeding, and intracellular levels of putrescine, spermidine, and spermine increased continuously during the cell cycle. In cells in the G₂/M phase of the cell cycle, putrescine and spermidine levels were twice as high as in cells in the G₁, phase. DNA distribution and polyamine levels were also analysed in cells taken directly from the various elutriation fractions enriched in G₁, S, or G₂/M. Because we did not obtain pure S or G₂/M populations by elutriation or by harvesting synchronized cells, a mathematical procedure—which assumed that the measured polyamine levels for any population were linearly related to the fraction of cells in the G₁, S, and G₂/M phases times the polyamine levels in these phases and that polyamine levels did not vary within these phases—was used to estimate ‘true’ phase-specific polyamine levels (levels to be expected if perfect synchrony were achieved). Estimated ‘true’ phase-specific polyamine levels calculated from the data obtained from cells either sorted by elutriation or obtained from synchronously growing cultures were very similar.     

Differential effects of nitrogen mustard in vivo on the cancer and host cells in MCa-11 tumours

We analysed the effects of nitrogen mustard (HN₂) on the growth, cell cycle distributions, and ratios of tumour cells to host cells for MCa-11 tumours grown in vivo. Treatment of tumour-bearing BALB/c mice with 3 mg/kg of HN₂ produced a significant slowing of MCa-11 tumour growth. Seventy-two hours after treatment in vivo with either 3 or 4 mg/kg of HN₂, the host cells in the treated tumours showed a significantly decreased G₀/G₁ peak and an increased G₂/M peak (P < 0.01), whereas the cancer cells in the treated tumours showed significant increases in the G₀/G₁ peak coupled with relatively decreased proportions of S and G₂/M tumour cells (P < 0.001). The ratio of the total number of cancer cells to the total number of host cells in the tumours was significantly increased 72 h after HN₂ administration (P<0.01). Thirty-two days after treatment with HN₂, the cell cycle distributions of the host and tumour cells in the treatment and control tumours had returned to being identical, but the ratio of the total number of cancer cells to the total number of host cells remained increased in the treated tumours (P<0.01). These results show that the administration in vivo of HN₂ can lead to entirely different cell cycle effects for the host and cancer cells in the same tumour, and that the partial growth arrest of MCa-11 tumours from HN₂ treatment may be due in part to the preferential destruction of host cells rather than solely to a direct cytotoxic effect on the cancer cells.     

Estrogen receptor alpha is cell cycle-regulated and regulates the cell cycle in a ligand-dependent fashion

Estrogen receptor alpha (ERα) has been implicated in several cell cycle regulatory events and is an important predictive marker of disease outcome in breast cancer patients. Here, we aimed to elucidate the mechanism through which ERα influences proliferation in breast cancer cells. Our results show that ERα protein is cell cycle-regulated in human breast cancer cells and that the presence of 17-β-estradiol (E2) in the culture medium shortened the cell cycle significantly (by 4.5 hours, P < 0.05) compared with unliganded conditions. The alterations in cell cycle duration were observed in the S and G₂/M phases, whereas the G₁ phase was indistinguishable under liganded and unliganded conditions. In addition, ERα knockdown in MCF-7 cells accelerated mitotic exit, whereas transfection of ERα-negative MDA-MB-231 cells with exogenous ERα significantly shortened the S and G₂/M phases (by 9.1 hours, P < 0.05) compared with parental cells. Finally, treatment of MCF-7 cells with antiestrogens revealed that tamoxifen yields a slower cell cycle progression through the S and G₂/M phases than fulvestrant does, presumably because of the destabilizing effect of fulvestrant on ERα protein. Together, these results show that ERα modulates breast cancer cell proliferation by regulating events during the S and G₂/M phases of the cell cycle in a ligand-dependent fashion. These results provide the rationale for an effective treatment strategy that includes a cell cycle inhibitor in combination with a drug that lowers estrogen levels, such as an aromatase inhibitor, and an antiestrogen that does not result in the degradation of ERα, such as tamoxifen.