Caffeine induces a second wave of apoptosis after low dose-rate gamma radiation of HL-60 cells

Most cell lines that lack functional p53 protein are arrested in the G₂ phase of the cell cycle due to DNA damage. It was previously found that the human promyelocyte leukemia cells HL-60 (TP53 negative) that had been exposed to ionizing radiation at doses up to 10 Gy were arrested in the G₂ phase for a period of 24 h. The radioresistance of HL-60 cells that were exposed to low dose-rate gamma irradiation of 3.9 mGy/min, which resulted in a pronounced accumulation of the cells in the G₂ phase during the exposure period, increased compared with the radioresistance of cells that were exposed to a high dose-rate gamma irradiation of 0.6 Gy/min. The D₀ value (i.e. the radiation dose leading to 37% cell survival) for low dose-rate radiation was 3.7 Gy and for high dose-rate radiation 2.2 Gy. In this study, prevention of G₂ phase arrest by caffeine (2 mM) and irradiation of cells with low dose-rate irradiation in all phases of the cell cycle proved to cause radiosensitization (D₀=2.2 Gy). The irradiation in the presence of caffeine resulted in a second wave of apoptosis on days 5–7post-irradiation. Caffeine-induced apoptosis occurring later than day 7 post-irradiation is postulated to be a result of unscheduled DNA replication and cell cycle progress.     

Chronic gamma-radiation sensitivity of skin fibroblasts from patients with non-Hodgkin's lymphoma (NHL)

Cultured skin fibroblasts from 11 patients with non-Hodgkin's lymphoma (NHL), 3 with ataxia telangiectasia (AT), 3 AT heterozygotes and 6 healthy subjects were studied for impaired colony-forming ability upon chronic exposure to gamma-radiation. A comparison of survival curves of the different cell lines revealed an AT heterozygote-like response (intermediate radiosensitivity) in 8 (73%) out of 11 NHL patients. These results suggested that the majority of the NHL patients may have an underlying abnormality of DNA repair.     

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.     

Cytogenetic characterization of ataxia telangiectasia (AT) heterozygotes using lymphoblastoid cell lines and chronic γ-irradiation

Summary Lymphoblastoid cell lines (LCLs) derived from two patients identified as ataxia telangiectasia (AT), two obligate AT heterozygotes and two controls (healthy subjects with no known genetic disease or relationship to AT patients) were compared with respect to the induction of chromosomal breaks by acute and chronic -irradiation. Although there was a considerable increase in the frequency of chromosomal breaks per cell in the LCLs of AT patients resulting from acute irradiation, the small increase occurring in the LCLs of the AT heterozygotes made it difficult to distinguish them from the controls. Following chronic -irradiation, however, the frequency of chromosomal breaks per cell in the LCLs of the AT heterozygotes occupied a significantly distinct position from that of the controls. These observations suggested that the use of chronic irradiation may be a better choice in the cytogenetic characterization of AT heterozygotes.     

EFFECTS OF IRRADIATION ON THE GENERATIVE CYCLE OF THE ESTROGEN STIMULATED VAGINAL EPITHELIUM

The effects of irradiation (300, 500 and 1500 rads) on mitosis and DNA synthesis in the estrogen primed vaginal epithelium have been studied. Dose-effect relations and the time sequence of effects on the two processes were investigated. The technique of tritiated thymidine labeling of DNA with autoradiography was used, in conjunction with the mitotic count, to study alterations in the generative cycle. Prior to irradiation, ovariectomized female rats were treated daily with diethylstilbestrol for a period of 2 weeks to create a steady state in the vaginal cell population. It was observed that:

• 1 Within 1 hr following ionizing radiation, mitotic figures disappear from the population and reappear at a time that is dose dependent. Those cells that have begun mitosis at the time of irradiation were able to complete that phase but no cells which were in G₂ were able to begin mitosis. Therefore, a G₂ block occurs within 1 hr post-irradiation.
• 2 Radiation reduces the rate of DNA synthesis thus prolonging the S phase. There is no evidence of a radiation-induced G₁ to S block in this system.

Based on these observations, it was further hypothesized that:

• 1 Cells in G₁ at the time of irradiation are relatively insensitive and continue to progress through the generative cycle at a rate primarily determined by the level of estrogen stimulation.
• 2 Radiation may interfere with the estrogen priming mechanism in this hormonedependent system thereby reducing the effective level of estrogen stimulation. This is seen in the behavior of cells which were in G₁ at the time of irradiation. The extent of the blockage of estrogen increases with radiation dose and after 1500 rads, estrogen stimulation is essentially at castrate level.

     

Chronic gamma-irradiation results in increased cell killing and chromosomal aberration with specific breakpoints in fibroblast cell strains derived from non-Hodgkin's lymphoma patients.

Cultured skin fibroblast cells from 6 patients with non-Hodgkin's lymphoma (NHL) and 2 clinically normal subjects were compared for cell survival and chromosomal aberration after chronic gamma-irradiation. Fibroblasts from an ataxia telangiectasia (AT) homozygote and an AT heterozygote were used as positive controls. Following irradiation, fibroblasts from all 6 NHL patients showed an increase in both cell death and chromosomal aberration (breaks and rearrangements) compared to the normal subjects. The difference in the frequency of chromosomal aberration between the normals and the NHL patients remained virtually unchanged over a period of 24-72 h post irradiation incubation of the cells. Cell cycle analysis by flow cytometry carried out in 1 normal and 1 NHL fibroblast cell strain showed that more cells representing the NHL patient were in G2/M phase compared to the normal at various times of cytogenetic analysis. While the AT homozygote appeared to be the most radiosensitive, the AT heterozygote showed a slightly higher incidence of cell death and chromosomal aberration than the normals. The cellular and chromosomal radiosensitivity of fibroblast cell lines from the NHL patients differed slightly from that of the AT heterozygote but clearly occupied an intermediate position between the AT homozygote and the normal subjects. Cells from 3 of the NHL patients showed radiation-induced specific chromosomal breaks involving chromosomes 1, 2, 6, 8, 10 and 11 which correspond to known fragile sites. Such breakpoints associated with increased radiosensitivity may be indicative of predisposition to malignancy in the patients studied.     

A novel radiosensitive SCID patient with a pronounced G2/M sensitivity

V(D)J rearrangement in lymphoid cells involves repair of double-strand breaks (DSBs) through non-homologous end joining (NHEJ). Defects in this process lead to increased radiosensitivity and severe combined immunodeficiency (RS-SCID). Here, a SCID patient, M3, is described with a T^?B⁺NK⁺ phenotype but without causative mutations in CD3δ, ?, ζ or IL7Rα, genes specifically involved in T cell development. Clonogenic survival of M3 fibroblasts showed an increased sensitivity to the DSB-inducing agents ionizing radiation and bleomycin, as well as the crosslinking compound, mitomycin C. We did not observe inactivating mutations in known NHEJ genes and results of various DSB-repair assays in G₁ M3 cells were indistinguishable from those obtained with normal cells. However, we found increased chromosomal radiosensitivity at the G₂ phase of the cell cycle. Checkpoint analysis indicated functional G₁/S and intra-S checkpoints after irradiation but impaired activation of the “early” G₂/M checkpoint. Together these results indicate a novel class of RS-SCID patients characterized by the specific absence of T lymphocytes and associated with defects in G₂-specific DSB repair. The pronounced G₂/M radiosensitivity of the RS-SCID patient described here, suggests a defect in a putative novel and uncharacterized factor involved in cellular DNA damage responses and T cell development.     

Transformation and repair replication in lymphocytes from ataxia telangiectasia

Peripheral blood leukocytes (PBL) isolated from five patients with ataxia telangiectasia (AT) proved more difficult to transform following addition of exogenous Epstein-Barr virus than PBL isolated from AT heterozygotes or normal adults. PBL isolated from one AT patient transformed within the range expected for normal PBL. Once established in culture, the resulting lymphoblastoid cell lines (LCLs) were immortal and, though they grew slower than normal control LCLs, provided useful material for studying cellular phenotypes associated with AT lymphoid cell lines. All the resulting LCLs established from ataxia were more sensitive to X-irradiation than were LCLs established from controls as measured by colony formation in microtiter plates. Furthermore, X-ray-induced inhibition of semiconservative DNA synthesis in ataxia LCLs was less than that seen in normal LCLs. These results are in agreement with those obtained using cultured AT fibroblasts, indicating that in vitro transformation by exogenously added Epstein-Barr virus does not alter the phenotype of the ataxia cell as measured by these two parameters. However, no deficiency in X-ray-induced excision repair of DNA was demonstrable in LCLs established from four AT patients. Nor was there a deficiency in AT LCL host cell reactivation of herpes simplex virus X-irradiated under anoxic conditions. Taken together, these data point toward a defect in ataxia lymphoblasts other than repair enzyme(s) per se, one possibly associated with chromosomal structure, function, or modification.     

Flow cytometry analysis of early DNA content changes in human and monkey cells following infection with simian virus 40

Simian virus 40 (SV₄₀) is capable of inducing cellular DNA synthesis in permissive and nonpermissive cells. Utilizing flow cytometry, we analyzed the DNA content changes in two diploid human cell strains and two monkey cell lines. The osteogenesis imperfects (OI) human skin fibroblasts were induced into DNA synthesis, and within one to two cell generations, a polyploid cell population was produced. With WI-38 phase II cells, a similar pattern of increased cycling of cells into DNA synthesis was observed; however, the majority (～60%) of the cells were blocked in the G₂ + M phase of the cell cycle. At later time intervals, an increase in the G₁ population was demonstrated. The two monkey cell lines responded to SV₄₀ virus with an accumulation of cells in the G₂ + M phase of the cell cycle. Thus, two diploid human cell strains exhibited different cell cycle kinetics early after infection with SV₄₀ virus. The one strain (WI-38) behaved similarly to the two monkey cell lines studied. The other strain (OI) responded similarly to nonpermissive (transformin) cells infected with SV₄₀ virus.     

Murine coronavirus replication induces cell cycle arrest in G0/G1 phase

Mouse hepatitis virus (MHV) replication in actively growing DBT and 17Cl-1 cells resulted in the inhibition of host cellular DNA synthesis and the accumulation of infected cells in the G₀/G₁ phase of the cell cycle. UV-irradiated MHV failed to inhibit host cellular DNA synthesis. MHV infection in quiescent 17Cl-1 cells that had been synchronized in the G₀ phase by serum deprivation prevented infected cells from entering the S phase after serum stimulation. MHV replication inhibited hyperphosphorylation of the retinoblastoma protein (pRb), the event that is necessary for cell cycle progression through late G₁ and into the S phase. While the amounts of the cellular cyclin-dependent kinase (Cdk) inhibitors p21^Cip1, p27^Kip1, and p16^INK4a did not change in infected cells, MHV infection in asynchronous cultures induced a clear reduction in the amounts of Cdk4 and G₁ cyclins (cyclins D1, D2, D3, and E) in both DBT and 17Cl-1 cells and a reduction in Cdk6 levels in 17Cl-1 cells. Infection also resulted in a decrease in Cdk2 activity in both cell lines. MHV infection in quiescent 17Cl-1 cells prevented normal increases in Cdk4, Cdk6, cyclin D1, and cyclin D3 levels after serum stimulation. The amounts of cyclin D2 and cyclin E were not increased significantly after serum stimulation in mock-infected cells, whereas they were decreased in MHV-infected cells, suggesting the possibility that MHV infection may induce cyclin D2 and cyclin E degradation. Our data suggested that a reduction in the amounts of G₁ cyclin-Cdk complexes in MHV-infected cells led to a reduction in Cdk activities and insufficient hyperphosphorylation of pRb, resulting in inhibition of the cell cycle in the G₀/G₁ 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.     

Modulation of G(2) arrest enhances cell death induced by the antitumor 1-nitroacridine derivative,Nitracrine

Nitracrine (Ledakrin) is an antitumor drug which is activated by cellular enzymes and binds covalently to DNA. Previous studies have shown that covalent binding and crosslinking of DNA is associated with the cytotoxic and antitumor activities of this compound. In this study, cell cycle perturbations, effects on DNA synthesis and the cell death process initiated by Nitracrine were studied in murine leukemia L1210 cells. We show that exposure of L1210 cells to Nitracrine at the IC₉₉ concentration delayed progression through the S phase and transiently arrested cells in G₂/M as found by flow cytometry. Higher drug concentration (2 × IC₉₉) inhibited cell cycle progression in the S phase and induced rapid cell death. Both studied concentrations of the drug produced different effects on DNA synthesis as determined by bromodeoxyuridine incorporation, with a delay in the S phase progression at EC₉₉ concentration and irreversible arrest in early S phase at the higher dose (2 × IC₉₉). At both concentrations of Nitracrine cell death occurred preferentially in the S phase as revealed by the TUNEL assay. When cells treated with the drug for 4 hours were post-incubated in the presence of 1 mM caffeine this led to rapid cell death and suppression of the G₂ arrest. This was associated with a about 10-fold increase in the cytotoxicity of Nitracrine. Similar effects were observed for another DNA crosslinking agent, cis-platinum, and to a lesser extent, for DNA topoisomerase I inhibitor, camptothecin. Together, our studies show that suppression of G₂ arrest induced by Nitracrine greatly enhances its cytotoxicity toward L1210 cells.     

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.     

DNA synthesis and cell cycle progression of synchronized L-cells after irradiation in various phases of the cell cycle

Summary The varying sensitivity to radiation in the different phases of the cell cycle was investigated using L-929 cells of the mouse. The cells were synchronized by mechanical selection of mitotic cells. The synchronous populations were X-irradiated with a single dose of 10 Gy in the middle of the G₁-phase, at the G₁/S-transition or in the middle of the S-phase, respectively. The radiation effect was determined in 2 h intervals a) by¹⁴C-TdR incorporation (IT) into the DNA, b) by autoradiography (AR), c) by flow cytometry (FCM). The incorporation rate decreased in all three cases, but the reasons appeared to be different, as can be derived from FCM and AR data: After irradiation in G₁, a fraction of cells was prevented from entering S-phase, after irradiation at G₁/S a proportion of cells was blocked in the S-phase, and after irradiation in S, DNA synthesis rate was reduced. As a consequence of these effects, the mean transition time through S-phase increased. The G₂ blocks, obtained after irradiation at the three stages of the cycle were also different: Cells irradiated in G₁ are partly released from the block after 10 h. Irradiation at G₁/S caused a persisting accumulation of 50% of the cells in G₂, and for irradiation in S more than 80% of the cells were arrested in G₂.     

THE SYNTHESIS OF ACIDIC CHROMOSOMAL PROTEINS DURING THE CELL CYCLE OF HELA S-3 CELLS : I. The Accelerated Accumulation of Acidic Residual Nuclear Protein before the Initiation of DNA Replication

The synthesis and accumulation of acidic proteins in the tightly bound residual nuclear fraction goes on throughout the cell cycle of continuously dividing populations of HeLa S-3 cells; however, during late G₁ there is an increased rate of synthesis and accumulation of these proteins which precedes the onset of DNA synthesis. Unlike that of the histones, whose synthesis is tightly coupled to DNA replication, the synthesis of acidic residual nuclear proteins is insensitive to inhibitors of DNA synthesis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of acidic residual nuclear proteins shows different profiles during the G₁, S, and G₂ phases of the cell cycle. These results suggest that, in contrast to histones whose synthesis appears to be highly regulated, the acidic residual proteins may have a regulatory function in the control of cell proliferation in continuously dividing mammalian cells.     

Houttuynia cordata Thunb extract modulates G0/G1 arrest and Fas/CD95-mediated death receptor apoptotic cell death in human lung cancer A549 cells

Background

Houttuynia cordata Thunb (HCT) is commonly used in Taiwan and other Asian countries as an anti-inflammatory, antibacterial and antiviral herbal medicine. In this study, we investigated the anti-human lung cancer activity and growth inhibition mechanisms of HCT in human lung cancer A549 cells.

Results

In order to investigate effects of HCT on A549 cells, MTT assay was used to evaluate cell viability. Flow cytometry was employed for cell cycle analysis, DAPI staining, and the Comet assay was used for DNA fragmentation and DNA condensation. Western blot analysis was used to analyze cell cycle and apoptotic related protein levels. HCT induced morphological changes including cell shrinkage and rounding. HCT increased the G₀/G₁ and Sub-G₁ cell (apoptosis) populations and HCT increased DNA fragmentation and DNA condensation as revealed by DAPI staining and the Comet assay. HCT induced activation of caspase-8 and caspase-3. Fas/CD95 protein levels were increased in HCT-treated A549 cells. The G₀/G₁ phase and apoptotic related protein levels of cyclin D1, cyclin A, CDK 4 and CDK 2 were decreased, and p27, caspase-8 and caspase-3 were increased in A549 cells after HCT treatment.

Conclusions

The results demonstrated that HCT-induced G₀/G₁ phase arrest and Fas/CD95-dependent apoptotic cell death in A549 cells     

Sensitivity to macrophage-mediated cytostasis is cell cycle dependent

We have examined the sensitivity of proliferating lymphoid cells in different phases of the cell cycle to macrophage-mediated cytostatic activity. These studies evaluated the ability of target cells enriched in individual cell cycle phases to pass into the next phase during brief (2–6 hr) periods of coculture with activated or nonactivated peritoneal macrophages. Both normal (concanavalin A-stimulated spleen cells) and neoplastic (Gross virus-induced thymic lymphoma) cells were analyzed. Spleen cells or lymphoma cells were first separated by centrifugal elutriation into populations highly enriched for G₁, S, or G₂/M phases of the cell cycle and cultured in the presence of nonactivated or activated macrophages for periods of 2, 4, or 6 hr. The cellular DNA content of recovered nonadherent target cells was then analyzed by flow cytometry after staining with propidium iodide. Macrophage contamination of target cell populations was insignificant under these conditions. Nonactivated macrophages did not affect target cell cycle traverse when compared with target cells cultured alone. Activated macrophage mediated cytostatic activity resulted in complete block of the transition of cells in G₁ phase into S phase and of the further accumulation of DNA by cells in early S phase. Cells already in mid to late S phase were able to continue DNA replication at rates nearly equivalent to control cells. There was no inhibition of the passage of cells through G₂ or mitosis. These effects were seen by as early as 2 hr of macrophage-target cell coculture and both normal and neoplastic cells exhibited identical patterns of cell cycle phase sensitivity.     

Polyamine biosynthesis and accumulation during the G1 to S phase transition

Ornithine decarboxylase, an important enzyme in growth regulation, is increased in CHO cells in G₁ phase of the cell cycle and decreases as the cells progress into S phase. S-adenosyl-L-methionine decarboxylase activity, which is dependent on either the presence of putrescine or spermidine for the synthesis of spermidine and spermine respectively, shows a maximal increase in late G₁/early S phase which corresponds very closely with the cell cycle phase specific accumulation of spermidine and spermine during S phase. Total culture evaluation of spermidine and spermine, which included extracellular as well as intracellular concentrations, indicated that extracellular accumulations of these polyamines occurred only in G₁ and that entry into S phase was concomitant with intracellular accumulation patterns. Hyperthermia (43°C for 1 hour) in mid-G₁ phase of the cell cycle resulted in rapid decreases in the activities of ornithine decarboxylase and S-adenosyl-L-methionine decarboxylase. In these cells, DNA replication was also not detectable until nine hours after mitosis, a time at which there had been recovery of ornithine decarboxylase and S-adenosyl-L-methionine decarboxylase activities. Previous data have further indicated a requirement for polyamine reaccumulation before control DNA replication rates are resumed. We therefore suggest that polyamine biosynthesis and intracellular accumulation are both temporal and quantitative prerequisites for transition through S phase.     

Radiosensitivity and recovery of mouse L cells during the cell cycle

Summary Mouse fibroblasts, subline L-929 F were synchronized by mitotic detachment. The synchronized cell cultures were irradiated with 200 kVp X-rays at different time after mitosis, and age reponse functions and dose effect curves were determined using the colony test. The cell age in the mitotic cycle was obtained from a computer analysis of flow cytometric DNA histograms. Both intrinsic radiosensitivity 1/D ₀ and extrapolation numbern were found to vary during the cell cycle. TheD ₀ has a maximum value of 176 ± 1 rad in the middle ofG ₁ phase and a minimum of 71 ± 1 rad at theS/G ₂ transition, while the extrapolation number is rather constant from the beginning ofG ₁ phase (1.9 ± 0.1) to the middle ofS phase (2.3 ± 0.1) and reaches a steep maximum of 9.3 ± 1.1 atS/G ₂ transition. The values ofn in the various phases of cell cycle are compared with the respective values of the recovery factor determined after fractionated irradiation. - Cell survival after a single dose of 616 rad has minima for irradiation atG ₁/S transition and in earlyG ₂ phase; the survival in earlyG ₂ being about 40 times smaller than in earlyG ₁ phase. Implications for a cell cycle specific therapy are discussed.Supported by the Deutsche Forschungsgemeinschaft, Bonn-Bad Godesberg