Caffeine increases sensitivity of DNA to denaturation in chromatin of L1210 cells

Abstract.
Exposure of exponentially growing L1210 cells to 5 mM and higher concentrations of caffeine perturbs their progression through the cell cycle and results in increased sensitivity of DNA in situ to denaturation. The latter is detected by the increased metachromatic stainability of DNA with acridine orange (AO) and sensitivity to S₁ nuclease, measured by flow cytometry. Decreased DNA stability is generally characteristic of chromatin condensation and in untreated cells is observed in mitosis or quiescence (G₀). The caffeine-induced decrease in DNA stability affects the interphase cells regardless of their position in the cycle and the changes are stochastic, concentration- and time-dependent. Populations of cells responding to caffeine are very heterogenous with respect to the degree of destabilization of DNA; sensitivity of DNA to denaturation of the maximally affected cells is similar to that of untreated cells in mitosis. The present method allows one to quantitatively express effects of caffeine on nuclear chromatin in individual cells of large cell populations and may be employed in studies correlating chromatin changes induced by this agent with its effects in modulation of cell sensitivity to radiation or antitumour drugs.     

RNA content and chromatin structure of CHO cells arrested in metaphase by colcemid

To evaluate the stability of cells arrested in metaphase, cell viability, RNA content, and chromatin structure (the latter probed by the DNA in situ sensitivity to acid-induced denaturation) were studied in uniform-age mitotic CHO cell populations maintained either at 37 degrees C (in the presence of Colcemid) or at 0-4 degrees C for up to 6 h. No significant changes in cell viability and RNA content were seen throughout the experiment for both groups of cells. The sensitivity of DNA in situ to denaturation was significantly increased during the initial 40 min of cell arrest in mitosis. However, no further chromatin changes for up to 6 h were evident regardless of whether cells were kept at 37 degrees C with Colcemid or at 0-4 degrees C in its absence. The data indicate that neither significant deterioration of metaphase cells nor progressive chromatin changes are expected during stathmokinesis experiments in vitro or during the metaphase cell arrest in cytogenetic studies lasting up to 6 h. Also, no RNA turnover can be detected in mitotic cells during this time interval.     

Changes in nuclear chromatin related to apoptosis or necrosis induced by the DNA topoisomerase II inhibitor fostriecin in MOLT-4 and HL-60 cells are revealed by altered DNA sensitivity to denaturation.

The antitumor drug fostriecin (phosphotrienin, FST) has been reported to exert its cytostatic and cytotoxic effects via inhibition of DNA topoisomerase II. The sensitivity of human lymphocytic leukemic MOLT-4 and promyelocytic HL-60 leukemic cells to a wide range of FST concentrations was studied by analyzing the cell cycle-specific effects and changes in nuclear chromatin induced by this inhibitor. The latter was evaluated by assaying the sensitivity of DNA in situ to acid-induced denaturation cytofluorimetrically, with the use of the metachromatic fluorochrome acridine orange (AO), which differentially stains double-stranded and denatured DNA. The cytostatic effects were observed soon after addition of FST (at concentrations of 1-30 microM for MOLT-4 cultures and 1-5 microM for HL-60 cultures) as a perturbation of cell progression through S and G2 phases of the cell cycle. Cell progression through the cycle was halted at greater than 30 microM FST in MOLT-4 cultures and at greater than 5 microM in HL-60 cultures; the effect was instantaneous and affected all phases of the cycle, so that no changes in the cell cycle distribution were apparent with increasing length of exposure to the drug. Instead, at these high FST concentrations, immediate cytotoxic effects became evident, manifesting either as cell apoptosis or necrosis. Apoptosis was observed only in the case of HL-60 cells, at FST concentrations of 5-100 microM, and was characterized by markedly increased sensitivity of DNA to denaturation combined with a decrease in overall DNA stainability, either with the DNA-specific dye DAPI or with AO, indicative of the activation of endogenous nucleases. Necrotic cell death was observed at FST concentrations of 1 mM and at greater than 30 microM for HL-60 and MOLT-4 cells, respectively: in both cases the overall DNA stainability, with either DAPI or AO, was unchanged compared to the control, but their DNA was very sensitive to denaturation. Interestingly, DNA in G2 and late S phase MOLT-4 cells, which were undergoing necrotic death, was much more sensitive to denaturation than was DNA in G1 cells of this lineage. The data indicate that chromatin changes induced by DNA topoisomerase II inhibitors in cells that undergo apoptotic or necrotic death can be conveniently monitored by the assay of DNA in situ sensitivity to denaturation.     

Comparative effects of caffeine on radiation- and heat-induced alterations in cell cycle progression

The effects of 3 mM caffeine on cell cycle progression of HeLa S3 cells exponentially and asynchronously growing in suspension culture were studied following exposure to 6.8 Gy gamma irradiation or 30 min at 45 degrees C hyperthermia. The stathmokinetic method, in which cells are grown in the presence of colcemid for the duration of experiment, in combination with two flow cytometric techniques, propidium iodide staining of DNA and acridine orange staining following acid denaturation of chromatin, were used to determine the fraction of cells in four cell cycle compartments, G1, S, G2, and M. Radiation and caffeine acted in a complementary manner, in which radiation reduced the caffeine-induced delays in cell cycle progression and caffeine prevented completely the radiation-induced accumulation of cells in G2 and mitotic delay. Heat and caffeine had additive effects on alterations in cell cycle progression. Cells containing spontaneous prematurely condensed chromatin were observed transiently immediately following heat exposure. These cells appeared to be in G2 and late S phase.     

Exposure to caffeine and suppression of DNA replication combine to stabilize the proteins and RNA required for premature mitotic events

Caffeine had been shown to induce mitotic events in Syrian hamster fibroblast (BHK) cells that were arrested during DNA replication (Schlegel and Pardee, Science 232:1264-1266, 1986). Inhibition of protein synthesis blocked these caffeine-induced events, while inhibition of RNA synthesis showed little effect. We now report that the protein(s) that are required for inducing mitosis in these cells were synthesized shortly after caffeine addition, the activity was very labile in the absence of caffeine, and the activity was lost through an ATP-dependent mechanism. Caffeine dramatically increased the stability of these putative proteins while having no effect on overall protein degradation. Experiments with an inhibitor of RNA synthesis indicated that mitosis-related RNA had accumulated during the suppression of DNA replication, and this RNA was unstable when replication was allowed to resume. These results suggest that the stability of RNA needed for mitosis is regulated by the DNA replicative state of the cell and that caffeine selectively stabilizes the protein product(s) of this RNA. Conditions can therefore be selected that permit mitotic factors to accumulate in cells at inappropriate times in the cell cycle. Two-dimensional gel electrophoresis has demonstrated several protein changes resulting from caffeine treatment; their relevance to mitosis-inducing activity remains to be determined.     

Rapid analysis of drug effects on the cell cycle

Using a flow cytometric technique to analyse DNA content and chromatin structure simultaneously, the following parameters of cell cycle progression were estimated in control and drug-treated L1210 cell cultures: (a) the kinetics of cell exit from the G1 phase; (b) the probability of cell exit from the indeterminate portion of the G1 phase, measured as the half-time of cell residence in that state; (c) the duration of the deterministic portion of G1 phase; (d) the rates of cell transit through selected "windows" in S phase; (e) the rate of cell entrance into mitosis; (f) the mean duration of the cell cycle (Tc). These parameters are obtained in a single stathmokinetic experiment from measurements of individual samples withdrawn at 30 min-1 hr intervals from Vinblasatine-treated cultures. In the same experiment mitotic indices are obtained with high statistical accuracy, and may be used to determine the terminal point of drug action. In addition to cell cycle analysis the method makes it possible to detect drug-induced changes in nuclear chromatin that are manifested by varying sensitivity of DNA in situ to denaturation by acid. Such changes were found to be associated with defective chromatin condensation, altered histone modifications or intercalation of the drugs into DNA. Using this technique the effects of sodium n-butyrate and two new antitumor drugs on L1210 cells were investigated.     

Initial chromosome damage but not DNA damage is greater in ataxia telangiectasia cells.

Cells derived from individuals with ataxia telangiectasia (AT) exhibit increased sensitivity to ionizing radiation and certain drugs (e.g., bleomycin, neocarzinostatin, and etoposide) as evidenced by decreased survival and increased chromosome aberrations at mitosis when compared with normal cell lines. To understand better the basis of this sensitivity, three AT and two normal lymphoblastoid cell lines were fractionated into cell cycle phase-enriched populations by centrifugal elutriation and then examined for their survival and their relative initial levels of DNA damage (neutral DNA filter elution) and chromosome damage (premature chromosome condensation). AT cells exhibited decreased levels of survival in all phases of the cell cycle; however, AT cells in early G1 phase were especially sensitive compared with normal cells in G1 phase. While AT and normal cells exhibited similar levels of initial DNA double-strand breaks in exponential populations as well as throughout the cell cycle, AT cells showed nearly twofold higher initial levels of chromosome damage than normal control cells in G1 and G2 phase. These results suggest that there is a higher rate of conversion of DNA double-strand breaks into chromosome breaks in AT cells, perhaps due to a difference in chromatin organization or stability. Thus one determining component of cellular radiosensitivity might include chromatin structure.     

Different sensitivity of DNA in situ in interphase and metaphase chromatin to heat denaturation

Heat denaturation of DNA in situ, in unbroken cells, was studied in relation to the cell cycle. DNA in metaphase cells denatured at lower temperatures (8 degrees-10 degrees C lower) than DNA in interphase cells. Among interphase cells, small differences between G1, S, and G2 cells were observed at temperatures above 90 degrees C. The difference between metaphase and interphase cells increased after short pretreatment with formaldehyde, decreased when cells were heated in the presence of 1 mM MgCl2, and was abolished by cell pretreatment with 0.5 N HCl. The results suggest that acid-soluble constituents of chromatin confer local stability to DNA and that the degree of stabilization is lower in metaphase chromosomes than in interphase nuclei. These in situ results remain in contrast to the published data showing no difference in DNA denaturation in chromatin isolated from interphase and metaphase cells. It is likely that factors exist which influence the stability of DNA in situ are associated with the super-structural organization of chromatin in intact nuclei and which are lost during chromatin isolation and solubilization. Since DNA denaturation is assayed after cell cooling, there is also a possibility that the extent of denatured DNA may be influenced by some factors that control strand separation and DNA reassociation. The different stainability of interphase vs. metaphase cells, based on the difference in stability of DNA, offers a method for determining mitotic indices by flow cytofluorometry, and a possible new parameter for sorting cells in metaphase.     

Effect of n-butyrate on cell cycle progression and in situ chromatin structure of L1210 cells

In the presence of 1–5 mM n-butyrate, murine leukemic L1210 cells cease proliferation and become arrested in the G1A compartment of the G1 phase. Cells in this compartment, in comparison with the remaining cells of the G1 phase (G1B), are characterized by low RNA content and more condensed chromatin. During unperturbed growth the cell residence times in G1A are of indeterminate duration (exponentially distributed); the half-time of L1210 cell residence in G1A is about 1.4 h. The effect of n-butyrate in arresting cells in G1A was concentration-dependent. However, the sensitivity of L1210 cells to this drug was markedly enhanced when cells were treated for longer than one generation (12 h). Cells arrested in G1A remained viable and when n-butyrate was removed, after a lag period, they resumed progression through the cycle.The effect of n-butyrate on cell progression through various parts of the cycle was studied in a stathmokinetic experiment. The rate of cell entrance into mitosis was decreased by 30, 60 and 110%, in the presence of 1, 2.5 and 5 mM n-butyrate respectively, thus indicating a slowdown in cell progression through G2 and S. The duration of G2 was prolonged by 20, 70 and 140% at 1, 2.5 and 5 mM n-butyrate respectively. The half-time of cell residence in G1A was increased by as much as 1.5-, 6.3- and 15.6-fold by 1, 2.5 and 5 mM n-butyrate. Progression through late G1 (G1B) was not affected at 1 mM, and could not be estimated at higher drug concentrations. The effects on cell cycle progression were evident 1 h after addition of n-butyrate.DNA in situ in nuclei of n-butyrate-treated cells had lowered (by 2–8 °C) stability to thermal denaturation and increased (by 15%) accessibility to DNase I. The decrease in DNA stability to heat was more pronounced when permealized cells were heated in the presence of 1 mM MgCl₂ rather than EDTA. DNA in situ in the nuclei of n-butyrate-treated cells also showed decreased sensitivity to acid-induced denaturation. Changes in chromatin were seen in all cells, regardless of cell cycle phase, within the first hours after addition of n-butyrate. Mitotic cells, however, reacted to n-butyrate more rapidly than interphase cells. The observed changes in L1210 cells are most likely a consequence of histone modifications (acetylation of inner histones, dephosphorylation of histone H1) induced by n-butyrate.     

Quantitative cytochemical changes induced by dexamethasone and adrenalectomy in rat liver chromatin

Physiochemical changes in the state of chromatin shortly following glucocorticoid stimulation of target cells are predicted by the proposed mechanism of steroid action. These changes had not been previously demonstrated in situ. The present experiments demonstrate that in the intact rat, or in one which has been adrenalectomized but given a moderate dose of dexamethasone, the thermal stability of liver cell chromatin is significantly reduced over the level observed in the adrenalectomized untreated animal. This alteration was rated by measuring nuclear acridine orange metachromasia following chromatin denaturation. These data also show an enhanced binding of the dye by the liver cell nuclei under the same conditions. Feulgen dye binding was also found to be enhanced by dexamethasone stimulation but to a level indicative of configurational changes in the chromatin rather than an increase in the amount of DNA in the cells.     

Caffeine overcomes a restriction point associated with DNA replication, but does not accelerate mitosis

Mitotic chromosome condensation is normally dependent on the previous completion of replication. Caffeine spectacularly deranges cell cycle controls after DNA polymerase inhibition or DNA damage; it induces the condensation, in cells that have not completed replication, of fragmented nuclear structures, analogous to the S-phase prematurely condensed chromosomes seen when replicating cells are fused with mitotic cells. Caffeine has been reported to induce S-phase condensation in cells where replication is arrested, by accelerating cell cycle progression as well as by uncoupling it from replication; for, in BHK or CHO hamster cells arrested in early S-phase and given caffeine, condensed chromosomes appear well before the normal time at which mitosis occurs in cells released from arrest. However, we have found that this apparent acceleration depends on the technique of synchrony and cell line employed. In other cells, and in synchronized hamster cells where the cycle has not been subjected to prolonged continual arrest, condensation in replication-arrested cells given caffeine occurs at the same time as normal mitosis in parallel populations where replication is allowed to proceed. This caffeine-induced condensation is therefore "premature" with respect to the chromatin structure of the S-phase nucleus, but not with respect to the timing of the normal cycle. Caffeine in replication-arrested cells thus overcomes the restriction on the formation of mitotic condensing factors that is normally imposed during DNA replication, but does not accelerate the timing of condensation unless cycle controls have previously been disturbed by synchronization procedures.     

Premature mitosis induced in mammalian cells by the protein kinase inhibitors 2-aminopurine and 6-dimethylaminopurine.

The protein kinase inhibitors 2-aminopurine (2-AP) and 6-dimethylaminopurine (6-DMAP) were used to examine the effects of protein dephosphorylation on the control of mitosis in mammalian cells. Both 2-AP and 6-DMAP induced premature mitosis in hamster fibroblasts that were arrested in S phase. This response was characterized by changes in cell morphology, breakdown of the nuclear envelope, and premature chromosome condensation. Premature mitosis was followed by a return to interphase morphology and reformation of the nuclear envelope around decondensed and fragmented chromatin to form numerous micronuclei. The activity of both compounds was dependent upon new protein synthesis but not new RNA synthesis. 2-AP and 6-DMAP acted cooperatively with each other and with caffeine, suggesting a common mechanism of action. In exponentially growing cells, 2-AP and 6-DMAP did not induce premature mitosis but did increase the frequency of binucleated cells by blocking cytokinesis. These findings support a role for protein dephosphorylation in the control of mitosis and indicate that cell cycle perturbations can modify this regulation.     

Recruitment of the cell cycle checkpoint kinase ATR to chromatin during S-phase

The ataxia telangiectasia-mutated (ATM) and Rad3-related kinase (ATR) is a central component of the cell cycle checkpoint machinery required to induce cell cycle arrest in response to DNA damage. Accumulating evidence suggests a role for ATR in signaling DNA damage during S-phase. Here we show that ATR is recruited to nuclear foci induced by replication fork stalling in a manner that is dependent on the single stranded binding protein replication protein A (RPA). ATR associates with chromatin in asynchronous cell cultures, and we use a variety of approaches to examine the association of ATR with chromatin in the absence of agents that cause genotoxic stress. Under our experimental conditions, ATR exhibits a decreased affinity for chromatin in quiescent cells and cells synchronized at mitosis but an increased affinity for chromatin as cells re-enter the cell cycle. Using centrifugal elutriation to obtain cells enriched at various stages of the cell cycle, we show that ATR associates with chromatin in a cell cycle-dependent manner, specifically during S-phase. Cell cycle association of ATR with chromatin mirrors that of RPA in addition to claspin, a cell cycle checkpoint protein previously shown to be a component of the replication machinery. Furthermore, association of ATR with chromatin occurs in the absence of detectable DNA damage and cell cycle checkpoint activation. These data are consistent with a model whereby ATR is recruited to chromatin during the unperturbed cell cycle and points to a role of ATR in monitoring genome integrity during normal S-phase progression.     

Microtubule stress modifies intra-nuclear location of Msh2 in mouse embryonic fibroblasts

The maintenance of genomic stability in mitotic and meiotic cycles through mismatch repair (MMR) demands the coordination of MMR functions with multiple processes including cell cycle traverse, linked changes in microtubule dynamics, protein translocation at chromatin sites and checkpoint activation. We have studied changes in the intracellular location of the MMR protein Msh2 in response to mitosis, microtubule disruption by colcemid and DNA damage induction by cis-platin in mouse embryonic fibroblasts (MEFs). Image analysis indicated that MEFs have a normally high nuclear retention of Msh2 during interphase with a precipitous dispersal of protein from chromatin sites into the cytoplasm at mitosis. Dispersal was also observed in cisplatin- and colcemid-treated interphase MEFs without any change in the overall Msh2 levels throughout the cell cycle. There was no evidence of co-localization of the punctate cytoplasmic Msh2 foci with any microtubule structures and knockout of Msh2 altered neither the extent of microtubule disruption nor the functional activation of the spindle assembly checkpoint by colcemid. Critically, extra-nuclear relocation of protein did not alter the ability to mount an Msh2-dependent G2 checkpoint delay in response to cisplatin-induced DNA damage. Depletion of the nuclear pool of Msh2 protein in cells undergoing dispersal was found to involve a rapid relocation of protein from AT-rich chromatin sites as defined by coassociation studies exploiting a newly-characterized base-pair preference of the fluorescent DNA binding probe DRAQ5. The study reveals the unexpected mobility of MMR protein pools during the MEF cell cycle and in response to different stress-inducing agents. The results link for the first time microtubule-integrity with intra-nuclear Msh2 protein dynamics. The high nuclear retention of Msh2 in interphase MEFs is in contrast to human tumor cells while the observations on protein dispersal suggest that only low levels of nuclear-located Msh2 are needed for G2 checkpoint activation by DNA damage.     

Microtubule Stress Modifies Intra-Nuclear Location of Msh2 in Mouse Embryonic Fibroblasts

The maintenance of genomic stability in mitotic and meiotic cycles through mismatch repair (MMR) demands the co-ordination of MMR functions with multiple processes including cell cycle traverse, linked changes in microtubule dynamics, protein translocation at chromatin sites and checkpoint activation. We have studied changes in the intracellular location of the MMR protein Msh2 in response to mitosis, microtubule disruption by colcemid and DNA damage induction by cis-platin in mouse embryonic fibroblasts (MEFs). Image analysis indicated that MEFs have a normally high nuclear retention of Msh2 during interphase with a precipitous dispersal of protein from chromatin sites into the cytoplasm at mitosis. Dispersal was also observed in cisplatin- and colcemid-treated interphase MEFs without any change in the overall Msh2 levels throughout the cell cycle. There was no evidence of co-localisation of the punctate cytoplasmic Msh2 foci with any microtubule structures and knockout of Msh2 altered neither the extent of microtubule disruption nor the functional activation of the spindle assembly checkpoint by colcemid. Critically, extra-nuclear relocation of protein did not alter the ability to mount an Msh2-dependent G2 checkpoint delay in response to cisplatin-induced DNA damage. Depletion of the nuclear pool of Msh2 protein in cells undergoing dispersal was found to involve a rapid relocation of protein from AT-rich chromatin sites as defined by co-association studies exploiting a newly-characterised base-pair preference of the fluorescent DNA binding probe DRAQ5. The study reveals the unexpected mobility of MMR protein pools during the MEF cell cycle and in response to different stress-inducing agents. The results link for the first time microtubule-integrity with intra-nuclear Msh2 protein dynamics. The high nuclear retention of Msh2 in interphase MEFs is in contrast to human tumour cells while the observations on protein dispersal suggest that only low levels of nuclear-located Msh2 are needed for G2 checkpoint activation by DNA damage.     

Cytofluorometric studies on conformation of nucleic acids in situ. II. Denaturation of deoxyribonucleic acid.

Thermal denaturation of deoxyribonucleic acid (DNA) in situ in individual unbroken cells is studied by a cytofluorometric method. This method allows us to investigate DNA denaturation in the presence of divalent cations at concentrations reported to be necessary to maintain native structure of nuclear chromatin. Under these conditions the pattern of DNA denaturation is very different than when studied in the presence of ethylenediaminetetraacetate or citrate. The results suggest that with divalent cations present, the histone basic charges are more uniformly distributed along whole nuclear DNA. Various cell types exhibit great differences in sensitivity to DNA denaturation when assayed in the presence of 1 mM MgCl2. Human lymphocytes, monocytes and certain kinds of human leukemic cells show differences large enough to be used as a parameter for their recognition in mixed samples. Possible applications of the method in basic research on chromatin conformation and as a tool for cell recognition in diagnostic cytology or in the classification of human leukemia are proposed.     

Changes in cell nuclei during S phase: progressive chromatin condensation and altered expression of the proliferation-associated nuclear proteins Ki-67, cyclin (PCNA), p105, and p34.

Using multiparameter flow cytometry we have measured the nuclear DNA content of exponentially growing HL-60 cells in conjunction with protein content, nuclear forward light scatter, DNA in situ sensitivity to denaturation, DNA accessibility to 7-aminoactinomycin D (7-AMD), and content of the proliferation-associated proteins: cyclin (PCNA), p105, p34, and Ki-67. Multivariate analysis of the data made it possible to correlate changes in each parameter with the degree of cell advancement through S phase (amount of replicated DNA). A decrease of the protein/DNA ratio, lowered DNA accessibility to 7-AMD, increased sensitivity of DNA to denaturation, and increased ability of isolated nuclei to scatter light all paralleled cell progression through S phase. These changes indicate that during S phase chromatin progressively condenses and suggest that the condensation is associated with the efflux of nonhistone proteins from the nucleus. The increase in the content of the antigen detected by the Ki-67 antibody was observed to exceed the increase in DNA content during S phase and the rate of the Ki-67/DNA increase was higher during the second half of S phase. Thus, this protein appears to be primarily synthesized during S, especially late in S phase, and is degraded in G1. The ratio of cyclin (PCNA)/DNA remained rather constant whereas the contents of p105 and p34 proteins, when expressed per unit of DNA, both decreased during S phase. The data indicate that significant changes in structure and composition of chromatin take place during S phase and suggest that the composition of chromatin associated with the nonreplicated DNA is different compared to chromatin associated with the newly replicated DNA.     

Denaturation of deoxyribonucleic acid in situ effect of formaldehyde.

In situ denaturation of nuclear deoxyribonucleic acid (DNA) is studied by use of acridine orange to differentially stain native versus denatured DNA, and a flow-through cytofluorometer for measurements of cell fluorescence. Thermal- or acid-induced DNA denaturation is markedly influenced by formaldehyde. Two mechanisms of the formaldehyde action are distinguished. If cells are exposed to the agent during heating, DNA denaturation is facilitated, most likely by the direct action of formaldehyde as a "passive" denaturing agent on DNA. If cells are pretreated with formaldehyde which is then removed, DNA resistance to denaturation increases, presumably due to chromatin cross-linking. It is believed that both effects occur simultaneously in conventional techniques employing formaldehyde to study DNA in situ, and that the extent of each varies with the temperature and cell type (chromatin condensation). Thus, profiles of DNA denaturation of cells heated with formaldehyde do not represent characteristics of DNA denaturation in situ; DNA denaturation under these conditions is modulated by the reactivity of chromatin components with formaldehyde rather than by DNA interactions with the macromolecules of nuclear mileu.     

Cell cycle age dependence for radiation-induced G2 arrest: evidence for time-dependent repair

Exponentially growing eucaryotic cells, irradiated in interphase, are delayed in progression to mitosis chiefly by arrest in G2. The sensitivity of Chinese hamster ovary cells to G2-arrest induction by X rays increases through the cell cycle, up to the X-ray transition point (TP) in G2. This age response can be explained by cell cycle age-dependent changes in susceptibility of the target(s) for G2 arrest and/or by changes in capability for postirradiation recovery from G2-arrest damage. Discrimination between sensitivity changes and repair phenomena is possible only if the level of G2-arrest-causing damage sustained by a cell at the time of irradiation and the level ultimately expressed as arrest can be determined. The ability of caffeine to ameliorate radiation-induced G2 arrest, while inhibiting repair of G2-arrest-causing damage makes such an analysis possible. CHO cell monolayers were irradiated (1.5 Gy), then exposed to 5 mM caffeine for periods of 0-10 hr. Cell progression was monitored by the mitotic cell selection procedure. In the presence of caffeine, progression of irradiated cells was relatively unperturbed, but on caffeine removal, G2 arrest was expressed. The duration of G2 arrest was independent of the length of the prior caffeine exposure and, since cells of all ages were ultimately examined, the duration of arrest was also independent of cell cycle age at the time of irradiation. This finding indicates that the target for G2-arrest induction is present throughout the cell cycle and that the level of G2-arrest damage incurred is initially constant for all cell cycle phases. The data are consistent with the existence of a time-dependent recovery mechanism to explain the age dependence for radiation induction of G2 arrest.     

DNA damage in synchronized HeLa cells irradiated with ultraviolet.

The lethal effect of UV radiation of HeLa cells is least in mitosis and greatest in late G1-early S. Photochemical damage to HeLa DNA, as measured by thymine-containing dimer formation and by alkaline sucrose sedimentation, also increases from mitosis towards early S phase. Computer simulations of UV absorption by an idealized HeLa cell at different stages of the cell cycle indicate that changes in damage could be due solely to changes in chromatin geometry. But survival is not exclusively a function of damage.