Two Molecularly Distinct G2/M Checkpoints Are Induced by Ionizing Irradiation

Cell cycle checkpoints are among the multiple mechanisms thateukaryotic cells possess to maintain genomic integrity and minimizetumorigenesis. Ionizing irradiation (IR) induces measurablearrests in the G₁, S, and G₂ phases of the mammalian cell cycle,and the ATM (ataxia telangiectasia mutated) protein plays arole in initiating checkpoint pathways in all three of thesecell cycle phases. However, cells lacking ATM function exhibitboth a defective G₂ checkpoint and a prolonged G₂ arrest afterIR, suggesting the existence of different types of G₂ arrest.Two molecularly distinct G₂/M checkpoints were identified, andthe critical importance of the choice of G₂/M checkpoint assaywas demonstrated. The first of these G₂/M checkpoints occursearly after IR, is very transient, is ATM dependent and doseindependent (between 1 and 10 Gy), and represents the failureof cells which had been in G₂ at the time of irradiation toprogress into mitosis. Cell cycle assays that can distinguishmitotic cells from G₂ cells must be used to assess this arrest.In contrast, G₂/M accumulation, typically assessed by propidiumiodide staining, begins to be measurable only several hoursafter IR, is ATM independent, is dose dependent, and representsthe accumulation of cells that had been in earlier phases ofthe cell cycle at the time of exposure to radiation. G₂/M accumulationafter IR is not affected by the early G₂/M checkpoint and isenhanced in cells lacking the IR-induced S-phase checkpoint,such as those lacking Nbs1 or Brca1 function, because of a prolongedG₂ arrest of cells that had been in S phase at the time of irradiation.Finally, neither the S-phase checkpoint nor the G₂ checkpointsappear to affect survival following irradiation. Thus, two differentG₂ arrest mechanisms are present in mammalian cells, and thetype of cell cycle checkpoint assay to be used in experimentalinvestigation must be thoughtfully selected.

INTRODUCTION

Top

Introduction

Genomic integrity is maintained by a complex network of checkpointsthat are defined as control mechanisms enforcing dependencyin the cell cycle. Within the cell cycle, both G₁-S and G₂-Mphase transitions are under constant surveillance for the protectionof cells from exogenous and endogenous DNA-damaging agents.These ordered dependencies are controlled by the regulationof certain gene products, mutations in which can result in alteredstress responses, increased mutation rates, or genetic instability(11). Investigating the mechanisms of genetic regulation ofcell cycle checkpoints thus contributes to an understandingof both cancer development and the responses of tumor cellsto chemotherapy and radiotherapy.

Ionizing irradiation (IR) induces arrests in the G₁, S, andG₂ phases of the cell cycle. A number of gene products thatcontrol each of these checkpoints have been identified, includingthe ATM (ataxia telangiectasia mutated) protein kinase, whichappears to be critical for initiation of each of these checkpointpathways (12). The ATM gene is mutated in the autosomal recessivedisease ataxia telangiectasia (AT), which is characterized bya pleiotropic phenotype including neuronal degeneration, oculocutaneoustelangiectasias, immune dysfunction, and cancer predisposition(24). Substrates and target sites of the ATM kinase have beenimplicated in control of the G₁ (p53, Chk2, and Mdm2) (1, 2,7, 16, 17, 18, 19, 25), S-phase (Nbs1 and Chk2) (9, 15, 33),and G₂ (Brca1 and hRad17) (3, 30) checkpoint pathways. Additionalsubstrates of ATM involved in these cell cycle control pathwaysare likely to be identified.

Reports in the literature characterizing the defect in G₂-to-Mprogression after IR in AT cells have presented apparent discrepancies.Some data demonstrate that AT cells fail to arrest in G₂ afterIR and continue to progress into mitosis (5, 20, 30, 32). Onthe other hand, other studies suggest that irradiated AT cellsexhibit a prolonged G₂ arrest after IR compared to cells fromnormal individuals (4, 23, 27). We investigated this apparentparadox and confirm that both phenotypic descriptions of cellslacking ATM activity are correct. We show that the conclusionsdrawn from assessment of the G₂ checkpoint abnormality in ATcells are dependent on the cell cycle assay that is utilizedand that two mechanistically distinct types of G₂ cell cyclearrests occur after IR.

MATERIALS AND METHODS

Top

Materials and Methods

Cell culture and irradiation. Epstein-Barr virus-immortalized lymphoblastoid cell lines fromhealthy persons (GM0536; NIGMS Human Mutant Cell Repository,Camden, N.J.) and from persons who were homozygous for the ATMmutation (GM 1526) or the NBS1 mutation (NBS7078A) were culturedin RPMI 1640 supplemented with 15% fetal bovine serum. Simianvirus 40 (SV40)-transformed human fibroblast cell lines froma normal donor (SVG; American Type Culture Collection, Manassas,Va.), AT patients (GM5849 and GM9607; NIGMS), and a Nijmegenbreakage syndrome (NBS) patient (NBS1-LBI, generously providedby Malgorzata Zdzienicka from Leiden University, Netherlands)(14), human 293T cells, and tumor cell lines (human cervix cancercell line HeLa, human neuroblastoma cell line SY5Y, and humanbreast cancer cell line HCC1937, all from the American TypeCulture Collection) were all grown as monolayers in Dulbecco'smodified Eagle medium supplemented with 10% fetal bovine serum.All cell lines were grown at 37°C in a humidified atmospherecontaining 5% CO₂. Radiation from a ¹³⁷Cs source was deliveredat a rate of approximately 120 cGy/min.

Expression of Nbs1 constructs in NBS cells and BRCA1 constructs in Brca1 mutant cells. We generated NBS1-LBI cell lines that stably express wild-typeNbs1 or mutant Nbs1 (serine 343 to alanine) by retroviral infection.For assessment of Nbs1/p95 expression in the infectants, totalcellular lysates were separated by sodium dodecyl sulfate-polyacrylamidegel electrophoresis in a 4 to 12% polyacrylamide precast gel(Invitrogen, Carlsbad, Calif.). Expressed Nbs1/p95 proteinswere detected by Western blot analysis with an anti-Nbs1/p95polyclonal antibody (Novus Biologicals Inc., Littleton, Colo.).Transfections of wild-type BRCA1 (generously provided by DavidLivingston) or mutant Brca1 (serine 1423 to alanine) into aBrca1-mutant cell line HCC1937, and transfections of wild-typeATM or kinase-dead ATM into 293T or HeLa cells were done transientlyby using Lipofectamine (Life Technologies, Rockville, Md.).For clonogenic survival assays in HCC 1937 cells transfectedwith Brca1 constructs, 1 mg of Geneticin (G-418; Life Technologies)per ml was added to the medium 36 h after transfection.

Flow cytometric analysis. (i) PI staining. Cells were harvested at various time points and fixed with 70%ethanol. Approximately 10⁶ cells were incubated with 25 µgof propidium iodide (PI; Sigma, St. Louis, Mo.) per ml, andDNA content was determined with a FACSCalibur (Becton Dickinson,San Jose, Calif.). Data were plotted by using CellQuest software;20,000 events were analyzed for each sample.

(ii) BrdUrd labeling and staining. Cells were pulse-labeled with 30 µM 5-bromo-2"-deoxy-uridine(BrdUrd; Boehringer Mannheim, Mannheim, Germany) for 30 minand then irradiated. At various time points, cells were harvestedand fixed in 70% methanol. Cells were then stained for bothDNA content and BrdUrd incorporation by the acid denaturation-proteasemethod by using fluorescein isothiocyanate (FITC)-conjugatedanti-BrdUrd (Becton Dickinson) as described previously (6).

(iii) Immunofluorescent detection of phosphorylated histone H3. Cells were harvested at various time points after IR and fixedin 70% ethanol at -20°C. After fixation, the cells wereresuspended in 1 ml of 0.25% Triton X-100 in phosphate-bufferedsaline (PBS) and incubated on ice for 15 min. After centrifugation,the cell pellet was suspended in 100 µl of PBS containing1% bovine serum albumin (BSA) and 0.75 µg of a polyclonalantibody that specific recognizes the phosphorylated form ofhistone H3 (Upstate Biotechnology, Lake Placid, N.Y.) and incubatedfor 3 h at room temperature. The cells were then rinsed withPBS containing 1% BSA and incubated with FITC-conjugated goatanti-rabbit immunoglobulin G antibody (Jackson ImmunoResearchLaboratories, Inc., West Grove, Pa.) diluted at a ratio of 1:30in PBS containing 1% BSA. After a 30-min incubation at roomtemperature in the dark, the cells were stained with PI andcellular fluorescence was measured by a flow cytometer.

S-phase checkpoint assay. Inhibition of DNA synthesis after irradiation was assessed aspreviously described (15, 20, 30). Briefly, cells were prelabeledwith 10 nCi of [¹⁴C]thymidine (NEN Life Science Products, Inc.,Boston, Mass.) for 24 h. Cells were irradiated and incubatedfor 30 min and pulse-labeled with 2.5 µCi of [³H]thymidine(NEN Life Science Products) per ml. Cells were harvested andfixed with 70% methanol. The amount of radioactivity was assayedin a liquid scintillation counter. The measure of DNA synthesiswas derived from resulting ratios of ³H to ¹⁴C counts per minute,corrected for counts that resulted from channel crossover.

Clonogenic assays. Cell lines were plated in triplicate at limiting dilutions intosix-well plates, incubated for 24 h, and then exposed to a rangeof doses of IR (0 to 6 Gy) followed by incubation for 2 weeks.Prior to colony counting, cells were fixed in 95% methanol andstained with crystal violet. A population of more than 50 cellswere counted as one surviving colony. The mean colony counts± standard errors are presented in the figures.

RESULTS

Top

Results

ATM-dependent and -independent G₂/M checkpoints. Cells from AT patients have previously been reported to exhibitboth a defective G₂ checkpoint (5, 20, 30, 32) and prolongedG₂ accumulation (4, 23, 27) after exposure to ionizing radiation.In order to try to more fully understand this apparent inconsistency,we evaluated the G₂ arrest in cells with normal or absent ATMfunction at various time points by two different assays. Whena recently developed assay that uses flow cytometric assessmentof histone H3 phosphorylation was used to distinguish mitoticcells from G₂ cells (30), cells with wild-type ATM functionwere found to stop entering mitosis within the first hour afterirradiation (Fig. 1A[first column] and B). By 12 h after irradiation,these cells release from G₂ and begin to reenter mitosis (Fig.1A [first column] and B). In fact, the cells appear to reentermitosis somewhat synchronously and actually exhibit an increasednumber of cells in mitosis between 12 and 48 h after irradiation.In contrast, cells lacking ATM function continue to enter mitosisafter irradiation (Fig. 1A [third column] and B), and the absolutepercentage of mitotic AT cells does not vary very much overtime after irradiation (Fig. 1B). These data are consistentwith prior observations that ATM is required for an IR-inducedG₂/M checkpoint and demonstrate the rapid nature of its initiationand the transience of the arrest. Though the particular cellsshown here for comparisons are not isogenic, we have previouslydemonstrated the critical dependency of this checkpoint assayon ATM kinase activity using isogenically comparable cells (30),and these data extend those previously published observationswith a more extensive kinetic analysis.

View larger version (34K):
[in this window]
[in a new window]
FIG. 1. Early G₂/M checkpoint and late G₂ accumulation. (A) Flow-cytometric profiles of cell cycle distribution before (0 h) and at the indicated time points after IR. Staining for DNA content (PI; y axis) and for histone H3 phosphorylation (FITC; x axis) is shown in the first and the third columns. M, mitotic cell population. DNA content (PI) is shown in the second and the fourth columns. (B) Ratio (irradiated/unirradiated) of mitotic cells (staining positive for phosphorylated histone H3) as a function of time after IR in HeLa [ATM(+/+)] and GM9607 [ATM(-/-)] cells. Error bars represent the variation around the averages of at least triplicate samples. (C) Percentage of total cells in G₂/M by PI staining as a function of time after 6 Gy of IR in HeLa [ATM(+/+)] and GM9607 [ATM(-/-)] cells. (D) Percentage of total cells in G₂/M (PI staining) as a function of time after 6 Gy of IR in HeLa cells transfected with vector alone (vector), wild-type ATM (wtATM), or kinase-dead ATM (kdATM). All G₂/M percentages are representative of at least three experiments.

If the G₂/M arrest is evaluated by assessing by the percentageof total cells with 4N DNA content by PI staining (representingcells in G₂ plus M), rather than directly assessing the percentageof just mitotic cells, a very different set of conclusions isreached. Cells with normal ATM function show an increase inthe number of cells with 4N DNA content within 12 h after irradiation(Fig. 1A [second column] and C). By 36 to 48 h after irradiation,the percentage of 4N-content cells with normal ATM functionreturns to baseline (Fig. 1A and C). In contrast, cells lackingATM exhibit an exaggerated and markedly prolonged accumulationof cells with 4N DNA content after IR (Fig. 1A [fourth column]and C). Similar results were obtained when isogenically comparablecells were examined (Fig. 1D). Thus, not only is ATM requiredfor the IR-induced accumulation of cells in G₂/M, but a lackof ATM actually results in an enhancement of this accumulation.In addition, the G₂ arrest evaluated by this yardstick occurslater and lasts longer than the arrest assessed by countingmitotic cells.

These observations support the concept that there are two separateperturbations of progression from G₂ into mitosis after IR.One of these occurs very early after IR and is dependent onATM and Brca1 (30). We define this as the early G₂/M checkpoint.The other response after IR, which we refer to as G₂ accumulation,is independent of ATM function and is actually enhanced by thelack of ATM. The explanation for the latter phenomenon is providedbelow.

Dose dependency of the two G₂ checkpoints. To further characterize these two distinct G₂ responses, theIR dose dependencies of the early G₂/M checkpoint and the G₂accumulation were assessed. The cessation of progression ofcells from G₂ into mitosis at early time points after irradiationwas independent of the IR dose used over a range of 1 to 10Gy (Fig. 2A).Though the amount of arrest was minimal in cellslacking ATM, these cells also exhibited no dose dependency inthis dose range (Fig. 2A, right). Decreases in the arrest becameapparent at doses less than 0.4 Gy (data not shown). In contrast,the amount of G₂ accumulation over time as assessed by PI stainingwas dose dependent between 1 to 10 Gy (Fig. 2B). Though quantitativedifferences were predictably observed, this dose dependencywas seen both in cells with ATM and in cells lacking ATM function.Though only these representative cell lines are shown here,several different cell lines with and without ATM function showedthe same characteristics. The dose of IR also influenced theduration of the G₂ accumulation, with higher doses leading tolonger accumulation periods (Fig. 2B). Thus, dose dependencyis another feature distinguishing the IR-induced early G₂/Mcheckpoint and G₂ accumulation.

View larger version (38K):
[in this window]
[in a new window]
FIG. 2. Dose dependency of the two distinct G₂ checkpoints. (A) Percentage of total cells in mitosis (staining positive for phosphorylated histone H3) at early time points after different doses of IR in HeLa [ATM(+/+)] and GM9607 [ATM(-/-)] cells. Error bars represent the variation around the averages of at least triplicate samples. (B) Dose dependency of G₂/M accumulation (PI staining) at various times after IR in HeLa [ATM(+/+)] and GM9607 [ATM(-/-)] cells. All results for are representative of at least three experiments.

Links between S phase and G₂ accumulation. The differences noted in the time courses of the early G₂/Mcheckpoint and the G₂ accumulation have certain implicationsfor mechanisms underlying the processes. Since the early G₂/Mcheckpoint is measurable very shortly after the irradiation,this arrest must reflect the failure of cells that were in G₂at the time of the irradiation to progress into mitosis. Incontrast, in order for the number of cells with 4N DNA contentto increase above that seen prior to irradiation, cells fromelsewhere in the cell cycle must be entering G₂/M (Fig. 3A).Inorder to formally demonstrate that the cells that were accumulatingin G₂/M had been at an earlier stage of the cell cycle at thetime of irradiation, cells were briefly pulse-labeled with thethymidine analog BrdUrd and then irradiated and harvested forflow-cytometric analysis at various times after irradiation.Uptake of the BrdUrd label identifies cells that were in S phaseat the time of irradiation. Twenty-four hours after irradiation,the majority of the cells remaining in G₂/M were positive forBrdUrd (Fig. 3B, top row, second column), demonstrating thatthe majority of cells remaining arrested were in S phase atthe time of irradiation. It is noted that the BrdUrd-positivecells do escape G₂ and progress back into the G₁ phase of thecycle (Fig. 3B, bottom row, second column). Thus, the G₂ accumulationdoes not appear to be a permanent arrest.

View larger version (32K):
[in this window]
[in a new window]
FIG. 3. Most cells accumulating in G₂/M after IR come from S phase. (A) Schematic representation of cell cycle progression after IR. Characterized checkpoints are labeled with asterisks. , G₁ checkpoint, which is p53 dependent and occurs at restriction point; , ATM-dependent S-phase checkpoint, which occurs throughout S phase; , G₂/M checkpoint, which is ATM dependent and occurs about 30 min prior to chromosome condensation. The early G₂/M checkpoint measures the inhibition of cells that are in G₂ at the time of IR from entering mitosis. G₂/M accumulation, which is ATM independent, measures the accumulation of cells that were in S phase (or G₁) at the time of irradiation. (B) HeLa [ATM(+/+)] and GM9607 [ATM(-/-)] cells were labeled with 30 µM BrdUrd for 30 min and then irradiated with 6 Gy. The top row shows flow-cytometric dot plots of BrdUrd labeling on the ordinate and DNA content on the abscissa before IR and 24 h after IR. The BrdUrd-positive cells (labeled R1) were gated and displayed as DNA content versus cell counts in the bottom row.

Examination of these cell cycle progression profiles in cellslacking ATM similarly demonstrated that the majority of cellsaccumulating in G₂/M are BrdUrd positive and thus were in Sphase at the time of irradiation (Fig. 3B, top row, fourth column).It is noted that some ATM-null cells irradiated during S phasesurvive and can make it back into G₁, even though these cellslack the IR-induced S-phase checkpoint. One major differencebetween cells with and without ATM was that fewer BrdUrd-positivecells had released from G₂/M and reentered G₁ by 24 h in cellswithout ATM (Fig. 3B, bottom row, fourth column). This observationis consistent with the enhanced accumulation in G₂/M seen inATM-null cells and further demonstrates that a lack of releaseof irradiated S-phase cells contributes to this enhanced accumulation.

Defective S-phase checkpoints lead to prolonged G₂ accumulation. Cells lacking ATM function lack the IR-induced S-phase checkpoint(20, 24) and exhibit prolonged G₂/M accumulation (Fig. 1 to3). Since the majority of cells accumulating in G₂/M were inS phase at the time of irradiation, we reasoned that perhapsit was the lack of an S-phase checkpoint that resulted in anenhanced G₂/M accumulation. Thus, we investigated whether othercell types lacking an S-phase checkpoint also exhibited prolongedG₂/M accumulation after IR. Nbs1 and Brca1 proteins are bothrequired for the IR-induced S-phase checkpoint (15, 30). Similarto ATM-null cells, both fibroblasts and lymphoblasts lackingNbs1 function exhibited the prolonged G₂/M accumulation phenotype(Fig. 4A and B).Similarly, HCC1937 cells, which lack Brca1 functionand lack an IR-induced S-phase checkpoint, exhibit an enhancedG₂/M accumulation after IR (Fig. 4C). In contrast, cells defectivein p53 function, either because of SV40 transformation (SVG)or lack of p53 expression (H1299), have an intact S-phase checkpoint,though they lack the IR-induced G₁ checkpoint (13). In contrastto the cells defective in ATM, Nbs1, or Brca1 function, thep53-defective cells do not exhibit a prolonged G₂/M accumulation(Fig. 4B and C). These data demonstrate a correlation betweena defective S-phase checkpoint and an enhanced G₂/M accumulationafter IR.

View larger version (28K):
[in this window]
[in a new window]
FIG. 4. Cell lines with defective S-phase checkpoint display prolonged G₂/M accumulation after IR. (A) Quantitation of G₂/M accumulation at various times after IR in normal (GM0536), AT (GM1526), and NBS (NBS7078A) lymphoblastoid cell lines. (B) Quantitation of G₂/M accumulation in normal (SVG), AT (GM9607), and NBS (NBS1-LBI) SV40-transformed fibroblast cell lines. (C) Quantitation of G₂/M accumulation at various times after IR in tumor cell lines with normal p53 function (SY5Y), lacking p53 (H1299), and lacking full-length Brca1 (HCC1937). All results are representative of at least three different experiments.

Since Nbs1 function is not required for the early IR-inducedG₂/M checkpoint (30), we can also conclude that prolonged G₂/Maccumulation does not correlate with the presence or absenceof the early G₂/M checkpoint. Since AT cells lack both the S-phasecheckpoint and the early G₂/M checkpoint, this conclusion couldnot have been reached by using ATM-null cells as a model. Toextend these concepts beyond simple correlation, we generatedisogenic cell lines for more formal evaluations of the linksbetween these IR responses. Cells lacking Nbs1 function werestably complemented with either empty vector, wild-type Nbs1,or Nbs1 with serine 343 mutated to alanine. Complementationwith wild-type Nbs1 restored the IR-induced S-phase checkpoint,while complementation with the S343A mutant, though it complementsseveral of the defects in NBS cells (15, 33), failed to complementthis particular defect (Fig. 5B).All of these NBS cells exhibita normal early G₂ checkpoint after IR (Fig. 5C). NBS cells complementedeither with vector alone or with the S343A Nbs1 mutant exhibitedthe increased G₂/M accumulation (Fig. 5D). In contrast, NBScells complemented with wild-type Nbs1, which restores the IR-inducedS-phase checkpoint, lost the enhanced G₂/M accumulation phenotype(Fig. 5D). Thus, a more formal link between the S-phase checkpointdefect and enhanced G₂/M accumulation after IR is established.

View larger version (35K):
[in this window]
[in a new window]
FIG. 5. Prolonged G₂ accumulation is correlated with the defective S-phase checkpoint but not the early G₂/M checkpoint. NBS1-LBI cells that had been stably infected with empty vector, wild-type Nbs1, or S343A Nbs1 were used in the various checkpoint assays. (A) Expression of transduced Nbs1 proteins assessed by immunoblotting. (B) Replicative DNA synthesis assessed 30 min after various doses of IR in the NBS1-LBI cell lines. (C) Quantitation of early G₂/M checkpoint data assessed by histone H3 phosphorylation in 293T cells transfected with empty vector or with kinase-dead ATM (293T+kdATM), an AT fibroblast cell line (GM5849), and the stable NBS cell lines. (D) Quantitation of percentage of total cells in G₂/M as a function of time after 6 Gy of IR in the isogenic NBS cell lines. All results are representative of at least three different experiment.

We had previously seen that the AT cells exhibiting the increasedaccumulation in G₂/M were primarily cells that had been in Sphase at the time of irradiation (Fig. 3B). We speculated thata failure to appropriately arrest in S phase after irradiationresulted in a prolonged arrest when the cells eventually gotto G₂. To directly establish this connection between lack ofarrest of irradiated S-phase cells and enhanced G₂/M accumulationlinkage, we performed BrdUrd pulse-label experiments with theseisogenically comparable cells. BrdUrd-positive NBS cells complementedwith either vector alone or S343A mutant Nbs1 arrested longerin G₂/M than NBS cells complemented with wild-type Nbs1 (Fig.6).Thus, the enhanced G₂/M accumulation appears to result primarilyfrom cells in S phase that fail to appropriately transientlyarrest in S phase in response to the irradiation.

View larger version (39K):
[in this window]
[in a new window]
FIG. 6. Inappropriate replicative DNA synthesis after IR leads to prolonged G₂/M accumulation. NBS1-LBI cells with stably introduced empty vector, wild-type Nbs1, or S343A Nbs1 were pulse-labeled with 30 µM BrdUrd 30 min before 6-Gy irradiation, and cells were harvested and analyzed at the indicated time points after IR. (A) The DNA content of cells that had taken up BrdUrd during the pulse period was examined at various times after IR. (B) Quantitation of the percentage of BrdUrd-positive NBS1-LBI cells in G₂/M as a function of time after IR. All results are representative of at least three different experiments. (C) HCC1937 cells transfected with empty vector, wild-type Brca1, or S1423A Brca1 were pulse-labeled with BrdUrd, and evaluations were performed as for panel A. (D) Quantitation of BrdUrd-positive HCC1937 cells in G₂/M as a function of time after IR. All results are representative of at least three different experiments.

NBS1-LBI cells, which exhibit prolonged G₂/M accumulation afterIR, lack the IR-induced S-phase checkpoint but have a normalearly G₂/M checkpoint. To further support the model linkingthe functionality of the S phase checkpoint to the magnitudeof the G₂/M accumulation, we also used cells with the conversephenotype (Table 1). HCC1937 cells, which lack Brca1 functionand are defective in both the IR-induced S-phase and early G₂/Mcheckpoints (30), exhibit the enhanced G₂/M accumulation phenotype(Fig. 4D). Both the S-phase and G₂ checkpoint defects are restoredif we complement these cells with wild-type Brca1, but onlythe S-phase checkpoint is restored if we complement them withBrca1 containing serine 1423 mutated to alanine so that it cannotbe phosphorylated (30). Thus, HCC1937 cells expressing S1423ABrca1 have a normal IR-induced S-phase checkpoint but lack theIR-induced early G₂/M checkpoint. This is the only cell typewe are aware of that has this particular phenotype. Using BrdUrdpulse-labeling and examining cell cycle progression of irradiatedS-phase cells after IR, we found that HCC1937 cells complementedwith either wild-type or S1423A Brca1 lose the enhanced G₂/Maccumulation phenotype (Fig. 6C and D). Since the cells complementedwith S1423A Brca1 still lack the early IR-induced G₂ arrest,this result convincingly demonstrates that the early IR-inducedG₂ checkpoint is mechanistically distinct from the G₂ accumulationphenotype. Furthermore, this again demonstrates that cells irradiatedduring S phase that fail to exhibit an appropriate transientcheckpoint will accumulate in G₂/M for a prolonged period oftime (Table 1).

View this table:
[in this window]
[in a new window]
TABLE 1. Association of prolonged G2 accumulation with defective S-phase checkpoint^a

Neither G₂/M checkpoint abnormality is linked to radiosensitivity. Saccharomyces cerevisiae cells with defective G₂/M checkpointsare hypersensitive to DNA-damaging agents (29). Since we hadgenerated cell lines selectively defective in one or the otherof these IR-induced G₂/M checkpoints, we investigated the potentialimpact of these checkpoints on radiation sensitivity. NBS cellscomplemented with Nbs1 protein mutated at serine 343 exhibitan abnormal S-phase checkpoint and prolonged G₂ accumulationbut have clonogenic survival similar to that of NBS cells complementedwith wild-type Nbs1 (Fig. 7A).Thus, radiation sensitivity doesnot result simply from loss of the S-phase checkpoint or exaggeratedG₂ accumulation. Conversely, HCC1937 cells complemented withBrca1 mutated at serine 1423 are defective in the early G₂/Mcheckpoint but exhibit clonogenic survival indistinguishablefrom that of cells complemented with wild-type Brca1 (Fig. 7B).Thus, within the limits of these assays, radiosensitivity canbe totally dissociated from each of these checkpoint defects.

View larger version (22K):
[in this window]
[in a new window]
FIG. 7. Radiation sensitivity and cell cycle checkpoint defects. (A) Expression of wild type Nbs1 (wtNbs1) or mutant Nbs1 (Serine 343 to alanine, S343A) rescues the hypersensitivity of NBS1-LBI cells in response to IR. (B) Expression of wild-type Brca1 (wtBrca1) or S1423A Brca1 rescues the radiation sensitivity of HCC1937 cells. Cells were exposed to 0 to 6 Gy of IR and incubated for 2 weeks prior to fixation, staining, and assessment of colony formation. The clonogenic survival assays were performed in triplicate. Standard errors are shown by error bars.

DISCUSSION

Top

Discussion

If the G₂ checkpoint is assessed in the first few hours afterirradiation, then cells that were in the G₂ phase of the cellcycle during irradiation are being evaluated. In order to beable to determine whether cells are progressing from G₂ intoM, the assay used in this setting must be able to distinguishmitotic cells from G₂ cells. This type of assessment revealsthat AT cells fail to arrest in G₂ after IR and continue toprogress into mitosis (20, 30, 32). On the other hand, if cellsare evaluated at later time points after irradiation, then thecells being evaluated would have been in S phase or even G₁at the time of irradiation. PI staining, which simply measuresthe DNA content of cells, is the most commonly used assessmentof G₂ arrest. In order for this assay to demonstrate an increasein the number of cells with 4N DNA content (representing G₂plus M), those cells must enter G₂/M from elsewhere in the cycle.We demonstrate here that G₂ arrest as measured by PI stainingis distinct from the ATM-dependent IR-induced G₂ checkpointand reflects accumulation of cells that had been irradiatedearlier in the cell cycle. In addition to different biochemicalcontrol mechanisms, these two pathways exhibit different kineticsand dose responses. Interestingly, if cells lack an IR-inducedS-phase checkpoint (which is true of cells lacking ATM, Nbs1,or Brca1), then they exhibit a prolonged arrest when they getto G₂ and show an enhanced G₂ accumulation. Definitive supportfor these concepts was facilitated by complementation experimentsusing characterized mutants of these genes important in theS-phase checkpoint. These experiments explain the apparent paradoxin the ATM literature about the nature of the G₂ checkpointdefect in AT and provide insights into two different mechanismsthat mammalian cells use to control cell cycle progression afterDNA damage.

Checkpoints are cellular mechanisms that prevent or delay progressionthrough the cell cycle when DNA is damaged or when crucial eventshave not been completed. In mammalian cells, loss of cell cyclecheckpoints has been linked with genetic instability and cancerformation (11). It is conceivable, however, that cells couldcompensate for loss of a checkpoint in certain settings, perhapsthrough initiation of a later checkpoint. Our data confirm thatradiosensitivity does not result from S-phase checkpoint defects(12) and also demonstrate directly that neither G₂/M arrestabnormality alone confers radiosensitivity. Since it has alsobeen previously shown that abrogation of the IR-induced G₁ checkpointdoes not confer radiosensitivity (26), it appears that abolitionof single checkpoints in mammalian cells does not directly conferradiosensitivity. However, blockade of two checkpoints couldact synergistically in creating genetic instability or decreasingcell viability. The observation that inhibition of the G₂ checkpointappears to more effectively sensitize cells to DNA damage ifthe cells also lack the G₁ checkpoint (10, 21, 22, 28, 31) isconsistent with this concept. In the experiments described here,the enhanced accumulation of irradiated cells in G₂ if theyfailed to arrest first in S phase might reflect such a compensationand theoretically could give cells more time to detect and repairreplicated damaged DNA. Such observations may have therapeuticimplications because they would predict that blockade of a particularcheckpoint pathway might have a more pronounced effect in acell already lacking a particular checkpoint (as might be seenin a tumor cell) than in a normal cell which has retained compensatorycheckpoints. Thus, targeting such pathways could have a beneficialtherapeutic index.

The mechanism by which cells that were irradiated during S phaseaccumulate in G₂ is clearly distinct from the mechanism thatkeeps irradiated G₂ cells from entering mitosis. The latterarrest is transient, dose independent, ATM and Brca1 dependent,and independent of Nbs1. In contrast, the former accumulationoccurs later, is dose dependent, and is ATM independent. Perhapsthe hyperaccumulation of cells in G₂ when the S-phase checkpointis defective reflects engagement of a DNA replication checkpoint.It is reasonable to postulate that if cells fail to appropriatelyarrest DNA synthesis in the presence of DNA double-strand breaks,then they would enter G₂ with DNA lesions that would be sensedas not fully or appropriately replicated. In S. cerevisiae,though there are clear distinctions between the pathways involvedin DNA damage checkpoints and DNA replication checkpoints, mutationsof some genes can alter both responses (8, 34). Building uponthe assays and observations presented here, we can begin toaddress the molecular controls of the G₂ accumulation and exploreoverlaps and distinctions with replication checkpoint pathwaysand DNA damage checkpoint pathways. Such insights could eventuallylead to novel approaches to selective sensitization of tumorslacking particular checkpoint pathways.

ACKNOWLEDGMENTS

We gratefully acknowledge the technical assistance of DianeWoods. We thank all members of the Kastan laboratory for helpfuldiscussions, Malgorzata Zdzienicka for providing the NBS1-LBIcell line, and David Livingston for providing the wild-typeBRCA1 cDNA.

This work was supported by grants from the National Instituteof Health (CA71378 and CA21765) and by the American LebaneseSyrian Associated Charities of the St. Jude Children's ResearchHospital.

FOOTNOTES

* Corresponding author. Mailing address: Department of Hematology-Oncology, St. Jude Children's Research Hospital, 332 N. Lauderdale St. Memphis, TN 38105. Phone: (901) 495-3968. Fax: (901) 495-3966. E-mail: Michael.Kastan{at}stjude.org.

Present address: Graduate School of Life Science and Biotechnology,Korea University, Sungbuk-ku, Seoul 136-701, Korea.

REFERENCES

Top