Abrogation of G(2)/M-phase block enhances the cytotoxicity of daunorubicin, melphalan and cisplatin in TP53 mutant human tumor cells

Irradiation of human melanoma (MeWo, Be11) and squamous cell carcinoma (4451, 4197) cells induces cell cycle blocks from which the cells recover to re-enter mitosis after 40-60 h. In the TP53 mutant cell lines, MeWo and 4451, irradiation induces a G(2)-phase block, where the fraction of cells in G(2) phase reaches a maximum after 18-20 h. In the TP53 wild-type cell lines, 4197 and Be11, a G(1)- and G(2)-phase block is reached 12 and 16 h postirradiation, respectively. Addition of pentoxifylline after irradiation at the time when the number of cells in G(2) phase has reached a maximum shortens the normal recovery from G(2)-phase block to approximately 7 h. Addition of daunorubicin, melphalan and cisplatin under these conditions markedly enhanced drug toxicity. In the TP53-mutated cell lines MeWo and 4451, the survival ratio at 7 Gy measured by colony formation was 2.3-2.8, 8.6-85 and 52-74 for daunorubicin, melphalan and cisplatin, respectively. In the TP53 wild-type cell lines, the corresponding survival ratios were found to be 1.3-1.4, 2.3-3.0 and 1.2-2.6, respectively. The survival ratios are for clonogenic survival after 7 Gy and 2 mM pentoxifylline and measure the influence of drug doses that ensure 95% survival in nonirradiated controls. The results indicate that the G(2)-phase block is a crucial event in the damage response that can be manipulated to achieve a significant enhancement of drug toxicity. These effects are particularly pronounced in TP53 mutant cells and are observed at drug doses well below the clinical range.     

Determination and synchronisation of G1-phase of the cell cycle in 2- and 4-cell mouse embryos

Incorporation of [3H]thymidine at different concentrations into mouse embryos at early developmental stages was determined by autoradiography. Methods to synchronise the G1-phase of mouse 2- and 4-cell embryos were also investigated. The results showed that the ability of embryos to incorporate [3H]thymidine increased with development. Embryos at the 4-cell stage were not labelled when the concentration of [3H]thymidine was lower than 5 microCi/ml, whereas the nuclei of embryos at morula and blastocyst stages began to show silver grains at a concentration of 0.1 microCi/ml of [3H]thymidine. After 2- and 4-cell mouse embryos were synchronised at the onset of G1-phase by treatment with low temperature or nocodazole, and DNA synthesis was detected by autoradiography, the duration of G1-phase was estimated. The result showed that 43% of the 2-cell embryos had a G1-phase of < or = 1 h, 22% had a G1-phase of < or = 2 h, 22% had a G1-phase of < or = 3 h and 13% had a G1-phase of < or = 4 h. The G1-phase in 85% of the 4-cell embryos was < or = 3 h, that in 8% of embryos was < or = 4 h and that in 7% of embryos was < or = 5 h. The toxicity of nocodazole on mouse embryo development was assessed based on both blastocyst formation and the number of blastomeres, and the results indicated that the effect of nocodazole on embryo development and cell cycle block was dose-dependent. The minimum concentration of nocodazole for metaphase block of mouse late 2-cell embryos was 0.05 microM, and the appropriate concentrations which did not impair development were 0.05-0.5 microM.     

Reversible G1 arrest in the cell cycle of human lymphoid cell lines by dimethyl sulfoxide

Proliferation of human B- and T-lymphoid cell lines including Raji and Akata cells was found to be arrested at the G1 stage in the cell cycle by dimethyl sulfoxide (DMSO). The G1 arrest by DMSO occurred gradually and was completed within 96 h after addition of 1.5% DMSO concomitantly with a decrease in growth rate. Progression of G1-phase cells containing a larger amount of RNA into S-phase began 9-12 h after removal of DMSO. At 24 h, the DNA pattern of the cell cycle was similar to that of nontreated log-phase cells. The expression of six differentiation markers on the lymphoid cells was not appreciably changed by treatment with DMSO. On the other hand, the expression of transferrin receptor (one of the growth-related markers) on G1-phase cells 96 h after addition of DMSO was decreased to one-fourth that on log-phase cells and was completely restored 24 h after removal of DMSO. These results indicate that DMSO, known as an inducer of differentiation in several myeloid cell lines, acts as an agent inducing G1 arrest in the cell cycle of the lymphoid cells.     

Events associated with the initiation of mitosis in fused multinucleate HeLa cells

Large multinucleate (LMN) HeLa cells with more than 10–50 nuclei were produced by random fusion with polyethylene glycol. The number of nuclei in a particular stage of the cell cycle at the time of fusion was proportionate to the duration of the phase relative to the total cell cycle. The fused cells did not gain generation time. Interaction of various nuclei in these cells has been observed. The nuclei initially belonging to the G1-or S-phase required a much longer time to complete DNA synthesis than in mononucleate cells. Some of the cells reached mitosis 15 h after fusion, whereas others required 24 h. The cells dividing early, contained a larger number of initially early G1-phase nuclei than those cells dividing late. The former very often showed prematurely condensed chromosome (PCC) groups. In cells with a large number of advanced nuclei the few less advanced nuclei could enter mitosis prematurely. On the other hand, the cells having a large number of nuclei belonging initially to late S-or G2-phase took longer to reach mitosis. These nuclei have been taken out of the normal sequence and therefore failed to synthesize the mitotic factors and depended on others to supply them. Therefore the cells as a whole required a longer period to enter mitosis. Although the nuclei became synchronized at metaphase, the cells revealed a gradation in prophase progression in the different nuclei. At the ultrastructural level the effect of advanced nuclei on the less advanced ones was evident with respect to chromosome condensation and nuclear envelope breakdown. Less advanced nuclei trapped among advanced nuclei showed PCC and nuclear envelope breakdown prematurely, whereas mitotic nuclei near interphase or early prophase nuclei retained their nuclear envelopes for a much longer time. PCC is closely related to premature breakdown of the nuclear envelope. Our observations clearly indicate that chromosome condensation and nuclear envelope breakdown are two distinct events. Kinetochores with attached microtubules could be observed on prematurely condensed chromosomes. Kinetochores of fully condensed chromosomes often failed to become connected to spindle elements. This indicates that the formation of a functional spindle is distinct from the other events and may depend on different factors.     

Prespore cell fate bias in G1 phase of the cell cycle in Dictyostelium discoideum

By generating a population of Dictyostelium cells that are in the G1 phase of the cell cycle we have examined the influence of cell cycle status on cell fate specification, cell type proportioning and its regulation, and terminal differentiation. The lack of observable mitosis during the development of these cells and the quantification of their cellular DNA content suggests that they remain in G1 throughout development. Furthermore, chromosomal DNA synthesis was not detectable these cells, indicating that no synthesis phase had occurred, although substantial mitochondrial DNA synthesis did occur in prespore cells. The G1-phase cells underwent normal morphological development and sporulation but displayed an elevated prespore/prestalk ratio of 5.7 compared to the 3.0 (or 3:1) ratio normally observed in populations dominated by G2-phase cells. When migrating slugs produced by G1-phase cells were bisected, each half could reestablish the 5.7 (or 5.7:1) prespore/prestalk ratio. These results demonstrate that Dictyostelium cells can carry out the entire developmental cycle in the G1 phase of the cell cycle and that passage from G2 into G1 phase is not required for sporulation. Our results also suggest that the population asymmetry provided by the distribution of cells around the cell cycle at the time of starvation is not strictly required for cell type proportioning. Finally, when developed together with G2-phase cells, G1-phase cells preferentially become prespore cells and exclude G2-phase cells from the prespore-spore cell population, suggesting that G1-phase cells have an advantage over G2-phase cells in executing the spore cell differentiation pathway.     

Changes in the DNA content of amoebae of Dictyostelium discoideum during growth and development.

A fluorimetric assay has been used to determine the DNA content of amoebae of Dictyostelium discoideum during growth and development. Amoebae grown in axenic culture tended to be multinucleate and had a greater DNA content than amoebae grown with a bacterial substrate, which were mononucleate. During the first 10 h of development there was little change in the DNA content of amoebae grown with a bacterial substrate, but the average DNA content per cell in amoebae grown axenically decreased as the amoebae became virtually mononucleate. Amoebae at 10 h development that had been harvested during exponential axenic growth were divided into two populations by countercurrent distribution in a polymer two-phase system. DNA content indicated that one population was largely in the G2-phase of the cell cycle, whereas the other population was largely in the G1-phase. Similar results were obtained at 10 h development with amoebae harvested during the stationary phase of axenic growth, although these amoebae start development all in the G2-phase of the cell cycle. Spores had a low DNA content, indicating that they were in G1-phase. It is proposed that all amoebae in G2-phase after early development differentiate, after mitosis, into spores and that stalk cells are formed from amoebae that remain in G1-phase after 10 h development.     

Cell cycle-dependent expression of phosphorylated histone H2AX: reduced expression in unirradiated but not X-irradiated G1-phase cells

Exposure of cells to ionizing radiation causes phosphorylation of histone H2AX at sites flanking DNA double-strand breaks. Detection of phosphorylated H2AX (gammaH2AX) by antibody binding has been used as a method to identify double-strand breaks. Although generally performed by observing microscopic foci within cells, flow cytometry offers the advantage of measuring changes in gammaH2AX intensity in relation to cell cycle position. The importance of cell cycle position on the levels of endogenous and radiation-induced gammaH2AX was examined in cell lines that varied in DNA content, cell cycle distribution, and kinase activity. Bivariate analysis of gammaH2AX expression relative to DNA content and synchronization by centrifugal elutriation were used to measure cell cycle-specific expression of gammaH2AX. With the exception of xrs5 cells, gammaH2AX level was approximately 3 times lower in unirradiated G(1)-phase cells than S- and G(2)-phase cells, and the slope of the G(1)-phase dose-response curve was 2.8 times larger than the slope for S-phase cells. Cell cycle differences were confirmed using immunoblotting, indicating that reduced antibody accessibility in intact cells was not responsible for the reduced antibody binding in G(1)-phase cells. Early apoptotic cells could be easily identified on flow histograms as a population with 5-10-fold higher levels of gammaH2AX, although high expression was not maintained in apoptotic cells by 24 h. We conclude that expression of gammaH2AX is associated with DNA replication in unirradiated cells and that this reduces the sensitivity for detecting radiation-induced double-strand breaks in S- and G(2)-phase cells.     

Oxygen enhancement ratio as a function of dose and cell cycle phase for radiation-resistant and sensitive CHO cells

There is still controversy over whether the oxygen enhancement ratio (OER) varies as a function of dose and cell cycle phase. In the present study, the OER has been measured as a function of survival level and cell cycle phase using volume flow cell sorting. This method allows both the separation of cells in different stages of the cycle from an asynchronously growing population, and the precise plating of cells for accurate measurements at high survival levels. We have developed a cell suspension gassing and sampling system which maintained an oxygen tension less than 20 ppm throughout a series of sequential radiation doses. For both radiation-resistant cells (CHO-K1) and a radiation-sensitive clone (CHO-xrs6), we could separate relatively pure populations of G1-phase, G1/S-boundary, S-, and G2-phase cells. Each cell line showed a typical age response, with cells at the G1/S-phase boundary being 4 (CHO-K1) to 12 (CHO-xrs6) times more sensitive than cells in the late S phase. For both cell lines, G1-phase cells had an OER of 2.3-2.4, compared to an OER of 2.8-2.9 for S-phase and 2.6-2.7 for G2-phase cells. None of these age fractions showed a dependence of OER on survival level. Asynchronously growing cells or cells at the G1/S-phase boundary had an OER similar to that of G1-phase cells at high survival levels, but the OER increased with decreasing survival level to a value near that of S-phase cells. These results suggest that the decrease in OER at high survival levels for asynchronous cells may be due to differences in the OERs of the inherent cell age subpopulations. For cells in one cell cycle stage, oxygen appears to have a purely dose-modifying effect.     

Cell-cycle progression during the development of Dictyostelium discoideum and its relation to the subsequent cell-sorting in the multicellular structures

Previous studies have shown that the cell-cycle phase at the onset of starvation is a naturally occurring variable that is closely involved in the subsequent sorting and differentiation of cells during Dictyostelium development. Here the cell-cycle progression during the development of D. discoideum Ax-2 cells and its relation to the subsequent cell-sorting were analyzed in detail using synchronized cells and their pulse-labeling by 5'-bromodeoxyuridine (BrdU). Measurements of cell number and nuclearity provided evidence that about 80% of cells progressed their cell-cycle after formation of multicellular structures (mounds). Many cells (T7 cells) starved at mid–late G2-phase (just before the PS-point from which cells initiate development when starved) progressed to the cell-cycle after mound formation. In contrast, a less amount of cells (T1 cells) starved at late G2-phase (just after the PS-point) progressed through the cell-cycle after mound formation. The significance of cell-cycle progression presented here is discussed, with reference to cell differentiation and pattern formation.     

Cell cycle dependent distribution of the proliferation-associated Ki-67 antigen in human embryonic lung cells

The cell cycle-dependent distribution of the proliferation-associated Ki-67 antigen has been evaluated immunocytochemically in L-132 human fetal lung cells. The cells were synchronized and cell cycle phases were determined: G1 = 6.7 h, S = 5.4 h, G2 = 8.5 h and mitosis = 1.3 h. The Ki-67 patterns were strictly correlated with the cell cycle phases. In late G1-phase, Ki-67 antigen was present only in the perinucleolar region. In the S-phase, Ki-67 staining was found homogeneously in the karyoplasm and in the perinucleolar region. G2-phase cells contained a finely granular Ki-67 staining in the karyoplasm with Ki-67-positive specks and perinucleolar staining. In early mitotic cells (pro- and metaphase) an intense perichromosomal Ki-67 staining was observed in addition to a homogeneously stained karyoplasm in prophase, and cytoplasm in metaphase. During ana- and telophase the Ki-67 antigen disappeared rapidly. In resting cells there was no Ki-67 staining.     

An association between the radiation-induced arrest of G2-phase cells and low-dose hyper-radiosensitivity: a plausible underlying mechanism?

The survival of asynchronous and highly enriched G1-, S- and G2-phase populations of Chinese hamster V79 cells was measured after irradiation with 60Co gamma rays (0.1-10 Gy) using a precise flow cytometry-based clonogenic survival assay. The high-dose survival responses demonstrated a conventional relationship, with G2-phase cells being the most radiosensitive and S-phase cells the most radioresistant. Below 1 Gy, distinct low-dose hyper-radiosensitivity (HRS) responses were observed for the asynchronous and G2-phase enriched cell populations, with no evidence of HRS in the G1- and S-phase populations. Modeling supports the conclusion that HRS in asynchronous V79 populations is explained entirely by the HRS response of G2-phase cells. An association was discovered between the occurrence of HRS and the induction of a novel G2-phase arrest checkpoint that is specific for cells that are in the G2 phase of the cell cycle at the time of irradiation. Human T98G cells and hamster V79 cells, which both exhibit HRS in asynchronous cultures, failed to arrest the entry into mitosis of damaged G2-phase cells at doses less than 30 cGy, as determined by the flow cytometric assessment of the phosphorylation of histone H3, an established indicator of mitosis. In contrast, human U373 cells that do not show HRS induced this G2-phase checkpoint in a dose-independent manner. These data suggest that HRS may be a consequence of radiation-damaged G2-phase cells prematurely entering mitosis.     

Flow cytometric analysis of G1- and G2/M-phase subpopulations in mammalian cell nuclei using side scatter and DNA content measurements

Several subcompartments of the cell cycle in addition to the G1-, S-, and G2-phases usually observed were identified by simultaneous flow cytometric measurements of ethidium bromide fluorescence and side scatter intensity of cell nuclei. Metaphase cells and very early G1-phase cells (G1A) with low side scatter intensities were discriminated from interphase cells with high side scatter intensities. The reason for the various side scatter intensities was found to be the different structure of metaphase cells and early G1-phase cells due to chromatin condensation as shown by sorting of the respective cell nuclei. The G1A-phase could further be subdivided into two compartments with very low side scatter (G1A1) and intermediate side scatter (G1A2) intensities. Using partially synchronized cells the duration of these subcompartments of the G1-phase could be estimated. The durations of G1A1- and G1A2-phases were found to be about 10 min and 20 min, respectively, compared to the total duration of the G1-phase of about 3 h. Additional flow cytometric measurements of side scatter intensities of cell nuclei provide therefore further information on subcompartments of the G1- and G2/M-phases.     

Cell cycle kinetic measurements in an irradiated rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine

Cell cycle kinetics after X-irradiation were studied in a solid rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine (BrdUrd) in cells in which the DNA was labeled by BrdUrd. It could be shown that this tumor was composed of about 80% diploid host cells, and only 20% of the cells in the dissociated tumor were actually tetraploid tumor cells. When rats were injected intraperitoneally with BrdUrd to label S-phase cells in the tumor, only a fraction of both types of cells became labeled with BrdUrd during S-phase, even 24 h after injection. The diploid BrdUrd-labeled cells progressed rapidly into cycle; 4 h after injection of BrdUrd, labeled diploid G1-phase cells could be observed. Only 25% of the tetraploid S-phase cells could be labeled by a single injection of BrdUrd (160 mg/kg body weight). These labeled tetraploid cells progressed through the cell cycle with similar velocities as did labeled diploid cells. Using a "Mini Osmotic Pump" containing bromodeoxycytidine (BrdCyd) at high concentration (0.3 mol/L) that released BrdCyd continuously into the organism where it was converted to BrdUrd, it could be shown that after 2 days about 60% of cells in S-phase and 70% of cells in G2-phase were labeled. The fraction of labeled G2-phase cells in irradiated tumors (D = 10 and 20 Gy) was enhanced between 10 and 50 h after irradiation due to a radiation-induced G2 block in cycling tetraploid tumor cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Frequency of mutagen-induced sister chromatid exchanges in the course of 3 cell cycles

The induction of SCE by fotrine (0.125 and 0.250 microgram/ml) and thiophosphamide (5 micrograms/ml) during the first three cell cycles was studied in the Chinese hamster cells. No increase in the SCE number was observed after treatment with thiophosphamide and fotrine at the G2 stage (the first stage from the moment of fixation) as compared with the control variants. The maximal sensitivity of the cells to the SCE induction by the mutagens is marked at the G1 stage of the first cell cycle before the moment of fixation. The level of SCE remains approximately the same in the second cell cycle before the moment of fixation (20-32 h) and decreased down to the control level at the G1 stage of the third cell cycle (48-52 h).     

Role of apoptosis in low-dose hyper-radiosensitivity

Little is known about the mode of cell killing associated with low-dose hyper-radiosensitivity, the radiation response that describes the enhanced sensitivity of cells to small doses of ionizing radiation. Using a technique that measures the activation of caspase 3, we have established a relationship between apoptosis detected 24 h after low-dose radiation exposure and low-dose hyper-radiosensitivity in four mammalian cell lines (T98G, U373, MR4 and 3.7 cells) and two normal human lymphoblastoid cell lines. The existence of low-dose hyper-radiosensitivity in clonogenic survival experiments was found to be associated with an elevated level of apoptosis after low-dose exposures, corroborating earlier observations (Enns et al., Mol. Cancer Res. 2, 557-566, 2004). We also show that enriching populations of MR4 and V79 cells with G(1)-phase cells, to minimize the numbers of G(2)-phase cells, abolished the enhanced low-dose apoptosis. These cell-cycle enrichment experiments strengthen the reported association between low-dose hyper-sensitivity and the radioresponse of G(2)-phase cells. These data are consistent with our current hypothesis to explain low-dose hyper-radiosensitivity, namely that the enhanced sensitivity of cells to low doses of ionizing radiation reflects the failure of ATM-dependent repair processes to fully arrest the progression of damaged G(2)-phase cells harboring unrepaired DNA breaks entering mitosis.     

How the Change from FLM to FACS Affected Our Understanding of the G1-Phase of the Cell Cycle

The frequency of labeled mitoses (FLM) method for analyzing cell-cycle phases necessitates a determination of cell-cycle interdivision times and the absolute lengths of the cell-cycle phases. The change to flow sorting (FACS) analysis, a simpler, less labor intensive, and more rapid method, eliminated determinations of absolute phase times, yielding only percents of cells exhibiting particular DNA contents. Without an interdivision time value, conversion of these fractions into absolute phase lengths is not possible. This change in methodology has led to an alteration in how the cell cycle is viewed. The FLM method allowed the conclusion that G1-phase variability resulted from constancy of S and G2 phase lengths. In contrast, with FACS analysis, slow growing cells exhibiting a large fraction of cells with a G1-phase amount of DNA appeared to be “arrested in G1 phase”. The loss of absolute phase length determinations has therefore led to the proposals of G1-phase arrest, G1-phase controls, restriction points, and G0 phase. It is suggested that these G1-phase controls and phenomena require a critical reevaluation in the light of an alternative cell-cycle model that does not require or postulate such G1-phase controls.     

Transformation abrogates an early G1-phase arrest point required for specification of the Chinese hamster DHFR replication origin.

The origin decision point (ODP) was originally identified as a distinct point during G1-phase when Chinese hamster ovary (CHO) cell nuclei experience a transition that is required for specific recognition of the dihydrofolate reductase (DHFR) origin locus by Xenopus egg extracts. Passage of cells through the ODP requires a mitogen-independent protein kinase that is activated prior to restriction point control. Here we show that inhibition of an early G1-phase protein kinase pathway by the addition of 2-aminopurine (2-AP) prior to the ODP arrests CHO cells in G1-phase. Transformation with simian virus 40 (SV40) abrogated this arrest point, resulting in the entry of cultured cells into S-phase in the presence of 2-AP and a disruption of the normal pattern of initiation sites at the DHFR locus. Cells treated with 2-AP after the ODP initiated replication specifically within the DHFR origin locus. Transient exposure of transformed cells to 2-AP during the ODP transition also disrupted origin choice, whereas non-transformed cells arrested in G1-phase and then passed through a delayed ODP after removal of 2-AP from the medium. We conclude that mammalian cells have many potential sites at which they can initiate replication. Normally, events occurring during the early G1-phase ODP transition determine which of these sites will be the preferred initiation site. However, if chromatin is exposed to S-phase-promoting factors prior to this transition, mammalian cells, like Xenopus and Drosophila embryos, can initiate replication without origin specification.     

Evidence for a role of heat-shock proteins in proliferation after heat treatment of synchronized mouse neuroblastoma cells

A role for heat-shock proteins (HSPs) in proliferation after heat treatment was considered in synchronized mouse neuroblastoma cells. For this purpose enhancement of HSP synthesis after heat treatment was inhibited by actinomycin D and the effect of this on cell cycle progression into mitosis and on cell survival was studied both in thermoresistant G1- and in thermosensitive late S/G2-phase cells. In G1-phase cells expression of basal and heat-induced HSP synthesis was the same as that in late S/G2-phase cells, which suggests that regulation of thermoresistance throughout the cell cycle is not directly linked with HSP synthesis. The synthesis of HSP36, HSP68, and HSP70 was enhanced after a 30-min treatment at 41-43 degrees C. Increase of HSP synthesis after heat shock was partly suppressed by the presence of 0.1 microgram/ml actinomycin D during heat treatment, while 0.2 micrograms/ml prevented enhancement of HSP synthesis completely. Suppression of heat-induced HSP synthesis by actinomycin D had the same concentration dependency in G1- and late S/G2-phase cells. Actinomycin D potentiated induction of mitotic delay by heat treatment (30 min, 42.5 degrees C) but only under conditions where it actually inhibited heat-induced enhancement of HSP synthesis. Heat-induced cell killing was also potentiated by actinomycin D. The potentiating effect of actinomycin D on heat-induced mitotic delay and on heat-induced cell killing was more pronounced in G1-phase cells than in late S/G2-phase cells. These results give evidence for a role of HSPs in the resumption of proliferation after heat treatment and suggest that heated G1-phase cells are more dependent on HSP synthesis for recovery of proliferation after heat treatment than heated late S/G2-phase cells.