Identification of MCM4 as a Target of the DNA Replication Block Checkpoint System*
Yukio Ishimi
,
Yuki Komamura-Kohno
,
Hyun-Ju Kwon
¶,
Kouichi Yamada || and
Makoto Nakanishi **
From the
Biomolecular and Technology Department, Mitsubishi Kagaku Institute of Life Sciences, 11 Minamiooya, Machida, Tokyo 194-8511, ||National Institute of Health and Nutrition, 1-23-1 Toyama, Shinjuku-ku, Tokyo 162-8636, and the **Department of Biochemistry and Cell Biology, Graduate School of Medical Sciences, Nagoya City University, 1 Kawasumi, Mizuho-cho, Mizuho-ku, Nagoya 467-8601, Japan
Received for publication, December 30, 2002
, and in revised form, April 18, 2003.
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ABSTRACT
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Inhibition of the progression of DNA replication prevents further initiation of DNA replication and allows cells to maintain arrested replication forks, but the proteins that are targets of the replication checkpoint system remain to be identified. We report here that human MCM4, a subunit of the putative DNA replicative helicase, is extensively phosphorylated in HeLa cells when they are incubated in the presence of inhibitors of DNA synthesis or are exposed to UV irradiation. The data presented here indicate that the consecutive actions of ATR-CHK1 and CDK2 kinases are involved in this phosphorylation in the presence of hydroxyurea. The phosphorylation sites in MCM4 were identified using specific anti-phosphoantibodies. Based on results that showed that the DNA helicase activity of the MCM4-6-7 complex is negatively regulated by CDK2 phosphorylation, we suggest that the phosphorylation of MCM4 in the checkpoint control inhibits DNA replication, which includes blockage of DNA fork progression, through inactivation of the MCM complex.
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INTRODUCTION
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The initiation of DNA replication in eukaryotes is triggered by activation of the MCM1 (27) complex, which is loaded with CDC6 and CDT1 onto replication origins to which ORCs are bound (13). The activation of the MCM complex requires phosphorylation of the MCM2 subunit by CDC7/DBF4 kinase and association of CDC45 with the origin region after the action of cyclin-dependent kinase. The MCM2-7 complex is the most likely candidate to act as the DNA replication helicase that catalyzes the unwinding of the DNA duplex during replication (4, 5). Although all MCM subunits possess a DNA-dependent ATPase motif in their central domain, DNA helicase activity is detected only with the MCM4-6-7 complex, which dimerizes to form a hexamer (69). Thus, it is possible that the MCM4-6-7 hexamer is an activated form of the MCM (27) hexamer, although other mechanisms leading to the activation of the MCM helicase activity have been proposed (10). MCM4 is phosphorylated in vivo at least in part by cyclin-dependent kinases, which probably leads to the inactivation of the MCM complex (11, 12). We reported previously (13) that the DNA helicase activity of the MCM4-6-7 complex is inhibited by the site-specific phosphorylation of MCM4 with CDK2-cyclin A. In Saccharomyces cerevisiae, it has been shown that cyclin-dependent kinases play a role leading to the exclusion of MCM4 from the nucleus (14). Other targets of the cyclin-dependent kinase activity that contribute to the negative regulation of DNA replication include ORC, CDC6, and CDT1 (15).
Cells normally protect the integrity of their genome from stresses such as ultraviolet light, ionizing radiation, alkylating reagents, and DNA replication blockage (1621). Treatment with hydroxyurea (HU), which inhibits ribonucleotide reductase, not only blocks the progression of DNA replication but also activates a DNA replication checkpoint system that is required to maintain genomic integrity. In the presence of HU or methyl methanesulfonate, the initiation of DNA replication at late origins is prevented (2224), and the arrested replication fork structure is maintained (25) by an active process that includes protein phosphorylation by the Mec1 and Rad53 kinases in S. cerevisiae. Recently, Sogo et al. (26) showed that the accumulation of single-stranded DNA and replication fork reversal occur at stalled replication forks in the absence of checkpoint control. It is plausible that these abnormal DNA structures lead to a loss of genome integrity. Mec1 with Rad3-1-1 kinases are known to be sensors of the arrested fork structure, and Rad53 is an effector kinase that is activated by its phosphorylation by Mec1. Several target proteins in the replication checkpoint pathway have been identified. Rad53 phosphorylates Dbf4 to attenuate the Cdc7/Dbf4 kinase activity (2729), and replication protein A, a single-stranded DNA-binding protein, is phosphorylated by Mec1 in an HU-dependent manner (30). The phosphorylation of DNA polymerase
is also regulated in this system (31). However, it remains unclear whether these targets are necessary and sufficient for the checkpoint reactions (32). In higher eukaryotes, ATR (Mec1 homolog), which binds to the arrested fork structure with other sensor proteins, phosphorylates CHK1, an effector kinase, leading to its activation (33, 34). Chinese hamster ovary cells lacking CHK1 function show a progressive change in the global pattern of replication origin firing in the absence of any DNA replication (34). Target protein(s) in the replication checkpoint system remain to be identified.
In this study we identified MCM4 as a target of the replication checkpoint system. The results suggest that the consecutive actions of ATR-CHK1 and CDK2 are required for the phosphorylation of MCM4. The phosphorylation of MCM4 should inhibit DNA replication through the inactivation of the MCM complex.
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EXPERIMENTAL PROCEDURES
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ReagentsCaffeine, hydroxyurea, and 2-aminopurine were purchased from Sigma, and Gö6976 was from Calbiochem. Aphidicolin was purchased from Wako Pure Chemical. Antibodies against CHK1 were purchased from Santa Cruz Biochemicals, and CDK2-Thr-160 phosphoantibodies were from Cell Signaling.
-Phosphatase was from New England Biolabs. Anti-MCM4 antibodies were obtained as reported (35).
Preparation of Cell Fractions and Western BlottingCells were lysed at 2 x 106 cells/100 µl in modified CSK buffer (10 mM Pipes, pH 6.8, 100 mM NaCl, 1 mM MgCl2, and 1 mM EGTA) containing 0.1% Triton X-100, 1 mM ATP, proteinase inhibitors (Pharmingen), and phosphatase inhibitors (10 mM sodium
-glycerophosphate, 5 mM sodium pyrophosphate, 1 mM sodium orthovanadate, and 50 mM sodium fluoride) (solution A) and placed on ice for 15 min. The cell suspension was centrifuged (5000 rpm for 5 min in a microcentrifuge), and the supernatant (S1) was saved. The recovered precipitate was suspended in solution A, and the supernatant obtained after centrifugation was saved (S2). The precipitate (P) was suspended in a volume of solution A to yield 4 x 106 cells/100 µl. In some experiments, the suspended P fractions were incubated with 1.4 units/µl of DNase I (Takara) for 15 min at 30 °C. The solution was centrifuged to obtain the soluble S4 fraction and the residual P' fraction. The Triton-soluble (S1 and S2) and chromatin-bound (S4, P', and P) fractions were electrophoresed through 10 (for MCM4 and CHK1) or 15% (for CDK2) acrylamide gels containing SDS and then transferred to membranes (Immobilon, Millipore). Membranes were incubated at 37 °C for 1 h with primary antibodies in blocking solution (Blockace, Dai-nippon Pharmaceuticals) or 5% bovine serum albumin in TBS (50 mM Tris-HCl, pH 7.5, and 0.15 M NaCl) plus 0.1% Triton X-100. After washing with TBS plus 0.1% Triton X-100, membranes were incubated with peroxidase-conjugated anti-rabbit or anti-mouse secondary antibodies (Bio-Rad). The immunoreacted proteins were detected using a chemiluminescent detection system (Super-Signal West Pico or Femto Maximum Sensitivity Substrate, Pierce), and the level of reactivity was quantified (Cool Saver AE-6935, Atto Instruments).
Preparation of Anti-phosphoantibodiesAntisera against phosphothreonine and phosphoserine at amino acids 7, 19, 32, 54, and 110 of human MCM4 were obtained by immunizing rabbits with a synthetic peptide of NH2-MSSPAS(pT)PSRRGSRRGRAC-COOH (for aa 7), NH2-SRRGRA(pT)PAQTPRSEC-COOH (for aa 19), NH2-CRSEDARS-(pS)PSQRRRG-COOH (for aa 32), NH2-CELQPMPT(pS)PGVDLQS-COOH (for aa 54), or NH2-CGTPRSGVRG(pT)PVRQRPDL (for aa 110); the antibodies were conjugated with the keyhole limpet at each amino terminus. Anti-phosphoantibodies were purified by phosphopeptide column chromatography. After the serum (10 ml) was loaded onto a phosphopeptide column (2 ml) that had been prepared by fixing the above peptides to CNBr-activated Sepharose, antibodies were eluted with 0.1 M glycine, pH 2.5, and 0.15 M NaCl. Eluted fractions were neutralized, dialyzed against phosphate-buffered saline, and then passed through a non-phosphopeptide-Sepharose column (2 ml). The material that passed through the column was concentrated and used as the anti-phosphoantibodies described below.
In Vitro PhosphorylationHuman CDK2-cyclin A complex was prepared as reported (13). Histidine-tagged human CHK1 and CHK2 proteins were expressed in insect cells using a baculovirus expression system (36, 37) and purified by nickel-nitrilotriacetic acid column chromatography according to the manufacturer's protocol (Qiagen). Human MCM4 and -6 genes were cloned into a pAcUW31 vector (7), and the MCM7 gene was cloned into a pVL1392 vector for baculoviral expression. An MCM4-6-7 complex containing histidine-tagged MCM4 was purified from the viral infected High5 cells by nickel-nitrilotriacetic acid column chromatography and then MonoQ column chromatography. The human MCM4-6-7 complex (50 ng) was incubated with increasing levels of CHK1 (120 and 400 ng) in 50 mM Hepes-NaOH, pH 8, 10 mM MgCl2, 2.5 mM EGTA, 1 mM dithiothreitol, and 100 µM [
-32P]ATP or incubated with CDK2-cyclin A (20, 60, and 200 ng) in 20 mM Tris-HCl, pH 7.5, 30 mM NaCl, 10 mM MgCl2, 0.01% Triton X-100, and 100 µM [
-32P]ATP. The reaction mixtures were incubated for1hat37 °C, and the products were analyzed by electrophoresis on 10% polyacrylamide gel containing SDS.
Purification of MCM4-6-7 Complex from HeLa CellsHeLa cells were cultured in the presence or absence of HU (2 mM) for 24 h. The harvested cells (
1 x 108 cells) were washed with phosphate-buffered saline and then stored at 80 °C. After thawing, the cells were suspended in modified CSK buffer containing phosphatase inhibitors (10 mM sodium
-glycerophosphate, 5 mM sodium pyrophosphate, 1 mM sodium orthovanadate, and 50 mM sodium fluoride) in the absence of Triton X-100 and kept at 0 °C for 15 min. The cell precipitate recovered after centrifugation was then suspended in CSK buffer containing 0.1% Triton X-100, 0.4 M NaCl, and phosphatase inhibitors and kept at 0 °C for 15 min. The recovered supernatant fraction contained about half the chromatin-bound MCM proteins. After centrifugation, the solubilized proteins were loaded onto a histone H3/H4 column (2 ml) that had been equilibrated with a buffer containing 0.3 M NaCl (6). The column was extensively washed with the same buffer, and proteins were eluted with a linear gradient of 0.32 M NaCl. The fractions containing MCM4, -6, and -7 proteins that were eluted with 0.60.9 M NaCl were pooled and concentrated with Centricon 30 (Amicon) in the presence of phosphatase inhibitors (Phosphatase Inhibitor Mixture 1 plus 2 from Sigma) and protease inhibitors. During the concentration, the solution was diluted to 0.15 M NaCl. The diluted and concentrated sample was further purified by glycerol gradient centrifugation. Fractions 36 of a total of 15 fractions were pooled and concentrated to 20 µl with Microcon (Amicon) after the addition of proteinase inhibitors. The concentrated sample, which contained
35 µg/ml proteins, was used for measuring the displacement of 17-mer oligonucleotide annealed to M13 single-stranded DNA by DNA helicase activity (6).
Another procedure was employed to obtain total cell extracts in the absence of phosphatase inhibitors. HeLa cells were washed with hypotonic buffer (20 mM Hepes, pH 7.5, 5 mM KCl, 1.5 mM MgCl2, and 1 mM dithiothreitol) and then homogenized with Dounce homogenizer (B pestle). Proteins extracted with 0.4 M NaCl in the same solution were loaded onto a histone H3/H4 column equilibrated with 0.3 M NaCl, and bound proteins were eluted by the linear gradient from 0.3 to 2 M NaCl. Fractions containing MCM4, -6, and -7 proteins were pooled and further purified by glycerol gradient centrifugation as described above, except that fractions obtained after glycerol gradient centrifugation were used without concentration for measuring DNA helicase activity.
UV Irradiation of HeLa CellsHeLa cells that were logarithmically growing in dishes (100 mm in diameter) were exposed to UV irradiation (100 J/m2) from a germicidal lamp (Toshiba GL15) at 2.5 J/m2 in the absence of growth medium. Fresh growth medium (Dulbecco's modified Eagle's medium plus 10% fetal bovine serum) was added to the cells, and they were cultured at 37 °C for the indicated periods. Cells harvested after incubation with trypsin/EDTA solution were washed with phosphate-buffered saline and stored at 80 °C before fractionation of the cells.
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RESULTS
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Phosphorylation of MCM4 in the Presence of HULogarithmically growing HeLa cells were cultured in the presence of HU for different periods (0, 4, 8, 16, and 24 h). After lysis, cells were fractionated into Triton-soluble (S1 and S2) and Triton-insoluble chromatin-bound fractions (P). The proteins in these fractions were reacted with anti-MCM4 antibodies (Fig. 1A, top panel). MCM4 was detected in both the soluble (S1) and the insoluble chromatin-bound (P) fractions isolated from cells cultured in the absence of HU. A portion of the MCM4 with slightly retarded mobility was detected in the P fraction. During incubation in the presence of HU, the level of MCM4 in the P fraction with retarded mobility gradually increased with maximal retardation observed after 16 h. In contrast, the mobility of the MCM4 in the S1 fraction did not change during the 24 h of incubation in the presence of HU. The alteration in the mobility of MCM4 appeared to be due to its phosphorylation because after
-phosphatase treatment it migrated to a position identical to that observed for the MCM4 isolated from the S1 fraction (Fig. 1B). The phosphorylation of CHK1 was examined during incubation of cells with HU (Fig. 1A, middle panel). Retardation of its mobility, which is due to phosphorylation by ATR (34), was detected over a time course similar to that observed for the hyperphosphorylation of MCM4. It remains to be determined why the total amount of CHK1 protein decreases after 24 h of incubation with HU.

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FIG. 1. HU-dependent hyperphosphorylation of MCM4. A, HeLa cells were cultured for the periods indicated in the presence of 2 mM HU. Triton-soluble fractions (S1 and S2) and the residual chromatin fraction (P) were prepared as described under "Experimental Procedures." These fractions (8 µl) were subjected to 10% PAGE and analyzed by immunoblotting with anti-MCM4 antibodies (top). The same fractions were also examined for CHK1 (middle) and CDK2-Thr-160 phosphorylation (bottom). B, chromatin-bound proteins prepared from HU-treated HeLa cells were solubilized by treating the chromatin fractions with DNase I, and the soluble chromatin fractions (8 µl) were incubated with increasing levels of -phosphatase (40 and 200 units) for 30 min at 30 °C under the conditions suggested by the manufacturer.
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Checkpoint-dependent Phosphorylation of MCM4 To address the question of whether the observed phosphorylation of MCM4 is due to the action of the DNA replication checkpoint system, caffeine, an inhibitor of ATR/ATM, which plays a central role in the checkpoint system, was added to the growth medium containing HU. As shown in Fig. 2 (top panel), this addition markedly reduced the hyperphosphorylation of MCM4 isolated from the P fraction. The reduced level of hyperphosphorylated MCM4 in the presence of caffeine appears to be associated with the dephosphorylation of CHK1 protein, which is evident from the mobility shift of retarded CHK1 to the basal position (Fig. 2, middle panel). To clarify the role played by CHK1 kinase in the hyperphosphorylation of MCM4, Gö6976, an inhibitor of CHK1 kinase (38) but not CDK2 kinase or CHK2 kinase activity (Fig. 3, A and B), was added to the medium containing HU. The drug inhibited the hyperphosphorylation in a dose-dependent manner (Fig. 3C, top panel). At a concentration of 600 nM, hyperphosphorylation of MCM4 was largely prevented, whereas phosphorylation of CHK1 protein itself was unaffected by Gö6976 (Fig. 3C, middle panel), indicating that this drug does not affect ATR kinase activity. These findings suggest that an ATR-CHK1 pathway is involved in the hyperphosphorylation of MCM4.

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FIG. 2. Caffeine blocks HU-induced hyperphosphorylation of MCM4. HeLa cells were cultured for 24 h in the presence or absence of 2 mM HU and 5 mM caffeine as indicated. Triton-soluble fraction (S1) and the chromatin fraction (P)(8 µl each) were examined for MCM4 (top panel), CHK1 (middle panel), and CDK2-Thr-160 phosphorylation (bottom panel) by immunoblotting analysis.
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FIG. 3. Influence of Gö6976 on the in vitro and in vivo phosphorylation of key proteins. A, in vitro effects of Gö6976 on the phosphorylation of CDC25c and MCM4. GST-CDC25c (120 ng) (36) was phosphorylated with human CHK1 (200 ng) (left panel) or human CHK2 (150 ng) (right panel) in the absence or presence of increasing levels of Gö6976 under the conditions described under "Experimental Procedures." Human MCM2-4-6-7 (90 ng) prepared from HeLa cells was incubated with CDK2-cyclin A (35 ng) under the same conditions (middle panel). Proteins were analyzed on 1525% polyacrylamide gel containing SDS followed by autoradiography. The positions of phosphorylated GST-CDC25c, CHK1, CHK2, cyclin A, MCM2 and -4 are indicated. Reactions with kinases as substrates were electrophoresed in the left-hand lanes of each gel. B, quantification of the inhibitory effect of Gö6976 on the phosphorylation of GST-CDC25c by CHK1 (Xes), CHK2 (open circles), and the phosphorylation of MCM2 and -4 by CDK2-cyclin A (filled circles). Radioactivity incorporated into each substrate in the absence of Gö6976 was taken as 100%. C, in vivo effect of Gö6976. HeLa cells were cultured for 24 h in the presence or absence of HU and increasing concentrations of Gö6976. Specific fractions prepared from the treated HeLa cells, as described under "Experimental Procedures," were examined for MCM4 (P fraction only, top), CHK1 (S1 only, middle), and CDK2-Thr-160 (S1 and S2, bottom) phosphorylation.
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Involvement of Cyclin-dependent Kinase in MCM4 PhosphorylationIn the presence of HU, ATR kinase phosphorylates CHK1 kinase, an effector kinase in the checkpoint system, to activate it in HeLa cells (Fig. 1A) (34). To identify the kinase responsible for MCM4 hyperphosphorylation in the presence of HU, we first phosphorylated the human MCM4-6-7 complex with a human CHK1 kinase preparation in vitro. Both MCM4 and -6 proteins in the complex appeared to be phosphorylated (Fig. 4A, right panel), but phosphorylation with CHK1 did not lead to the generation of highly phosphorylated forms of MCM4 (Fig. 4B, 1st column on the left panel). In contrast, MCM4 products with retarded mobility were generated by phosphorylation with CDK2-cyclin A (Fig. 4, A, left panel, and B, 1st column on the left panel). We reported previously (39) that mouse MCM4 in an MCM4-6-7 complex was extensively phosphorylated with CDK2-cyclin A and that this phosphorylation inhibited the DNA helicase activity of the complex. Phosphorylation in this system of mutant mouse MCM4-6-7 complexes, where amino acids of MCM4 were altered in a site-specific manner, indicated that six sites (Ser-3, Thr-7, Thr-19, Ser-32, Ser-53, and Thr-109) in the amino-terminal region of mouse MCM4 were required for the phosphorylation of MCM4 (13). Specific phosphoantibodies against three (Ser-32, Ser-54, and Thr-110) of these sites in human MCM4 were raised, and they were examined for binding to the phosphorylated MCM4 (Fig. 4B). They interacted with the MCM4-phosphorylated product formed with CDK2-cyclin A but not with the phosphorylated MCM4 product formed with CHK1 (Fig. 4B, 2nd to 4th columns on the left panel). Next, we examined the interaction of these phosphoantibodies with MCM4-hyperphosphorylated products produced in the presence of HU (Fig. 4B, 2nd to 4th columns on the right panel). These phosphoantibodies recognized the hyperphosphorylated MCM4 products that were isolated from the chromatin fractions (S4 and P') of HU-treated HeLa cells. Quantification of the level of binding of these phosphoantibodies indicates that phosphorylation of MCM4 in the chromatin fractions increased by 2.56-fold in the presence of HU. These results strongly suggest that cyclin-dependent kinase activity is involved directly in the HU-induced hyperphosphorylation of MCM4.

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FIG. 4. Phosphorylation of MCM4 by cyclin-dependent kinase. A, human MCM4-6-7 complex (50 ng) was incubated with increasing amounts of CDK2-cyclin A (left panel) or CHK1 (right panel). Phosphorylated proteins were analyzed by electrophoresis on 10% polyacrylamide gel, followed by autoradiography. The maximal level of 32P incorporated into MCM4 by CDK2 was 2.3 mol/mol of MCM4 and that of 32P incorporated into MCM4 + MCM6 by CHK1 was 4 mol/mol of MCM4 + MCM6. B, left panel, human MCM4-6-7 complex was phosphorylated by CHK1 or CDK2-cyclin A in vitro, and products were analyzed by SDS-PAGE. Proteins were analyzed by Western blotting using MCM4 antibodies (1st column) and phosphoantibodies against amino acids Ser-32, Ser-54, and Thr-110 of MCM4 (2nd to 4th columns), as indicated. Right panel, the soluble (S1) and chromatin-bound fractions (S4 and P') prepared from HeLa cells treated with HU were analyzed by Western blotting using MCM4 and the anti-phosphoantibodies. Bars at the left of gels indicate the normal position of unphosphorylated MCM4.
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To gain more insight on the mechanism by which MCM4 is hyperphosphorylated by a cyclin-dependent kinase, we monitored the activation of CDK2 by examining its phosphorylation at Thr-160 (40) during the incubation of HeLa cells with HU (Fig. 1A, bottom panel). Phosphorylation of Thr-160 increased 23-fold after 16 and 24 h of the incubation with HU. The addition of caffeine (Fig. 2, bottom panel) or Gö6976 (Fig. 3C, bottom panel) decreased the level of phosphorylated CDK2 produced in the presence of HU. These results indicate that the activation of CDK2 kinase activity correlates with the increased level of MCM4 hyperphosphorylation induced by HU.
Functional Significance of Phosphorylation of MCM4 To understand the functional significance of phosphorylation of MCM4, DNA helicase activity was compared between MCM4-6-7 complexes prepared from HU-treated and non-treated HeLa cells. After extraction of a large portion of the soluble forms of the MCM complex, approximately half the chromatin-bound MCM complex was recovered by extraction of the remaining insoluble fraction with a buffer containing 0.4 M NaCl (data not shown). The MCM4-6-7 complex was purified from the 0.4 M NaCl-soluble fraction of HU-treated HeLa cells and non-treated cells in the presence phosphatase inhibitors, and it was also purified from total cell extracts of non-treated cells in the absence of phosphatase inhibitors as described under "Experimental Procedures." As shown in Fig. 5A, these three MCM4-6-7 complexes exhibited similar protein compositions and concentration, although only a slight amount of MCM2 was detectable in the complexes prepared from HU-treated cells in the presence of phosphatase inhibitors and from non-treated cells in the absence of phosphatase inhibitors. Two MCM4 bands that migrated closely on a gel were detected from the complex prepared from non-treated cells in the absence or presence of phosphatase inhibitors, although the ratio of these two bands varied between the two complexes. Only one MCM4 band with retarded mobility was detected in the MCM4-6-7 complex prepared from HU-treated cells in the presence of phosphatase inhibitors. It is probable that these two MCM4 bands differed in terms of the level of phosphorylation as described below. The DNA helicase activity of the purified MCM4-6-7 complexes was examined (Fig. 5, C and D). The MCM4-6-7 complex prepared from non-treated HeLa cells in the absence of phosphatase inhibitors exhibited the activity in a dose-dependent manner. However, the complex prepared from non-treated and HU-treated cells in the presence of phosphatase inhibitors showed a reduced level of the helicase activity. These three preparations of MCM4-6-7 complexes were examined for the phosphorylation status of MCM4 by using anti-phosphoantibodies (Fig. 5B). In addition to the three antibodies (Ser(P)-32, Ser(P)-54, and Thr(P)-110), two other antibodies (Thr(P)-7 and Thr(P)-19) were used for the detection of phosphorylation of MCM4 (Fig. 5B). As shown in Fig. 5B, panel at the far right, almost identical amounts of MCM4 were loaded onto the gels. It appears that partial dephosphorylation of MCM4 occurred during the purification of the MCM4-6-7 complex even in the presence of phosphatase inhibitors, because highly phosphorylated forms of MCM4 with retarded mobility were not evident in the purified complex prepared from HU-treated cells. However, immunoblotting studies using these five phosphoantibodies show that MCM4 in the MCM4-6-7 complex prepared from HU-treated cells and non-treated cells in the presence of phosphatase inhibitors is more phosphorylated than MCM4 in the complex prepared from non-treated cells in the absence of phosphatase inhibitors. These results suggest that the DNA helicase activity of MCM4-6-7 complex is negatively regulated by phosphorylation of MCM4 at these five sites. This notion is supported by the findings showing that DNA helicase activity of mouse MCM4-6-7 complex is inhibited by the site-specific phosphorylation (Ser-3, Thr-7, Thr-19, Ser-32, Ser-53, and Thr-109) of MCM4 with CDK2-cyclin A (13). These results also indicate that phosphorylation of MCM4 at these sites occurs even in the absence of HU.

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FIG. 5. DNA helicase activity of MCM4-6-7 complex purified from HU-treated HeLa cells. A, MCM4-6-7 complex was purified from HU-treated (sample 3) or non-treated (sample 2) HeLa cells in the presence of phosphatase inhibitors, or it was purified from non-treated HeLa cells in the absence of phosphatase inhibitors (sample 1) as described under "Experimental Procedures." Proteins in the purified complex separated by SDS-gel electrophoresis were stained with silver. Two aliquots (0.5 and 1 µl) of these samples were loaded onto the gel. Total protein concentration of sample 1 was determined as 35 µg/ml when bovine serum albumin was used as a standard. B, 2 µl of each sample was loaded onto SDS gel to analyze phosphorylation status of MCM4 protein using five different anti-phosphoantibodies as indicated at the top of the gel. The number above the gels indicates the sample number, as shown in A. C, DNA helicase activity that displaces a 17-mer oligonucleotide annealed to M13 single-stranded DNA was measured. Five different volumes of samples 13 were added to the helicase reaction. D, the helicase activity was quantified by measuring a proportion of the displaced oligonucleotide in the sum of annealed and displaced oligonucleotides. Dose-response curves of samples 13 were shown, where an average of two independent measurements was adopted.
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Aphidicolin- and UV-dependent Phosphorylation of MCM4 To examine whether phosphorylation of MCM4 is stimulated by other DNA-damaging reagents, HeLa cells were incubated in the presence of aphidicolin, which is an inhibitor of DNA polymerases including DNA polymerase
, or they were exposed to UV irradiation (Fig. 6). In the presence of aphidicolin, phosphorylation of both MCM4 and CHK1 proteins was stimulated (Fig. 6A). Addition of 2-aminopurine, which is another inhibitor of ATR/ATM kinase (41), inhibited the HU-dependent phosphorylation of MCM4 and CHK1 proteins. We believe that bands detected in the P fractions when anti-CHK1 antibodies were used as a probe are not CHK1 proteins. The HU-dependent phosphorylation of MCM4 and CHK1 proteins was partially prevented by the presence of caffeine (data not shown). During incubation after UV irradiation, phosphorylation of both MCM4 and CHK1 proteins was gradually stimulated (Fig. 6B). At 3 h after the irradiation, the level of MCM4 phosphorylation was maximal, and the level had decreased at 6 and 14 h of incubation after the exposure (data not shown). The increase in the level of the phosphorylation of MCM4 in the cells cultured for 3 h after UV irradiation was partially inhibited when the irradiated HeLa cells were cultured in the presence of caffeine. The phosphorylation of CHK1 was slightly inhibited in the presence of caffeine. HeLa cells were also incubated with methyl methanesulfonate, an alkylating reagent, or camptothecin, an inhibitor of topoisomerase I, but checkpoint-dependent phosphorylation of MCM4 was not detected (data not shown). These results suggest that phosphorylation of MCM4 was stimulated when DNA synthesis was prevented or DNA was damaged by UV irradiation. It is possible that stimulation of MCM4 phosphorylation occurred when DNA synthesis was uncoupled from the movement of the DNA replication fork.

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FIG. 6. Phosphorylation of MCM4 in the presence of aphidicolin or after UV irradiation. A, logarithmically growing HeLa cells were cultured in the presence or absence of aphidicolin (15 µM) and 2-aminopurine (2-AP) (5 or 10 mM) for 24 h as indicated. The cells were fractionated into soluble S (S1 plus S2) and insoluble P fractions, and proteins in these fractions were separated by SDS-gel electrophoresis for analysis of MCM4 and CHK1 proteins. B, HeLa cells were exposed to UV irradiation (100 J/m2) and then cultured for indicated periods in the absence or the presence of caffeine (5 mM). Soluble S and insoluble P fractions were analyzed for MCM4 and CHK1 proteins.
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DISCUSSION
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We report here that MCM4, a subunit of the putative replicative DNA helicase, is phosphorylated in the presence of inhibitors of DNA synthesis or after exposure to UV irradiation. ATR and the downstream kinase CHK1 are involved in the activation of a DNA replication checkpoint in the presence of HU in HeLa cells (34). Consistent with this observation, our results suggest that an ATR-CHK1 pathway is mainly responsible for the hyperphosphorylation of MCM4 in the presence of HU. It should be noted, however, that neither caffeine nor Gö6976 completely block the MCM4 phosphorylation, suggesting that another pathway is also involved in the phosphorylation. Although it is possible that CHK1 phosphorylates MCM4 directly in the presence of HU, the results presented here suggest that a cyclin-dependent kinase is mainly responsible for the observed phosphorylation. We propose that the ATR-CHK1 pathway somehow activates CDK2 activity in the presence of HU to phosphorylate MCM4 (Fig. 7). In agreement with this notion, it has been reported that an assembly factor of CDK-activating kinase, which activates CDK2 by phosphorylating it at Thr-160, interacts with MCM7 (42).

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FIG. 7. Proposed transduction pathway leading to the hyperphosphorylation of MCM4 and the targets of inhibitors used in this study. We speculate that in the presence of HU the ATR-CHK1 pathway activates CDK2 activity leading to the phosphorylation of MCM4.
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Regarding the role of cyclin-dependent kinase in the DNA replication checkpoint system, Pellicioli et al. (31) have reported that the phosphorylation of the B subunit of DNA polymerase
in S. cerevisiae is negatively regulated by the presence of HU. They suggested that the kinase activity of Cdk1, which phosphorylates the B subunit, is inhibited in a Rad53-dependent manner. It has been reported (43) that the Srs DNA helicase, which may be involved in the processing of stalled replication forks, is phosphorylated in the presence of HU in a Rad53-dependent reaction. In contrast to the phosphorylation of the B subunit of DNA polymerase
, phosphorylation of the Srs helicase required the action of the cyclin-dependent kinase Cdk1. These results suggest that two opposing reactions, one leading to the activation and one resulting in the inhibition of Cdk1 activity, are involved in the replication checkpoint system. An important role of CDK2 in other checkpoint systems has been reported; the G1 checkpoint in hematopoietic cells leads to the activation of CDK2 (44).
The MCM2-7 proteins play a central role in the initiation and elongation of DNA replication. It is likely that they act as a DNA-unwinding enzyme in DNA replication. We reported that the DNA helicase activity of the human and mouse MCM4-6-7 complex, a sub-complex of the MCM2-7 heterohexamer, is inhibited by the phosphorylation by CDK2-cyclin A (13, 39). We identified six sites, including Ser-32, Ser-53, and Thr-109, in the amino-terminal region of mouse MCM4 that are required for the phosphorylation with CDK2-cyclin A. Changes of these sites to alanine made the mutant MCM4-6-7 complex resistant to inhibition of the DNA helicase activity by CDK2-cyclin A, indicating that the site-specific phosphorylation of MCM4 with CDK2-cyclin A causes the inhibition of DNA helicase activity (13). The finding that phosphorylation of MCM4 at these sites was stimulated in the presence of HU suggests the notion that the replication checkpoint-dependent phosphorylation of MCM4 results in the inhibition of DNA replication through the inactivation of the MCM complex. We presented evidence showing that the MCM4-6-7 complex prepared from HU-treated HeLa cells exhibited a reduced level of DNA helicase activity, but the MCM4-6-7 complex prepared from non-treated HeLa cells also exhibited a reduced level of the activity. Comparison of the phosphorylation status among these two MCM complexes and the MCM4-6-7 complex, which is more active as a DNA helicase, suggests that the phosphorylation of MCM4 at Thr-7, Thr-19, Ser-32, Ser-54, and Thr-110 is involved in lowering the helicase activity. These results suggest that the DNA helicase activity of the MCM4-6-7 complex prepared from the chromatin-bound fraction of non-treated HeLa cells is negatively regulated by phosphorylation of MCM4 with cyclin-dependent kinase, and the treatment of HeLa cells with HU stimulates the phosphorylation of MCM4 with the kinase.
Because MCM is the most likely candidate for the replicative helicase that is responsible for the replication fork movement, it is possible that the phosphorylation of MCM4 explains phenotypic events observed upon activation of the replication checkpoint control system in S. cerevisiae and Chinese hamster ovary cells. Inhibition of MCM helicase activity by CDK2 may be involved in preventing the accumulation of single-stranded DNA at stalled replication forks that was detected in S. cerevisiae (26) and preventing the initiation of DNA replication in the presence of checkpoint control (22, 23, 34). Thus, we propose that MCM4 is one of the crucial targets of the DNA replication checkpoint system.
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FOOTNOTES
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* This work was supported in part by a grant-in-aid from the Ministry of Education, Science, Technology, Sports and Culture, Japan. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. 
¶ Present address: Dept. of Life Science & Biotechnology, College of Natural Science, Dong-Eui University, Korea. 
To whom correspondence should be addressed. Tel.: 81-42-724-6266; Fax: 81-42-724-6314; E-mail: yukio{at}libra.ls.m-kagaku.co.jp.
1 The abbreviations used are: MCM, minichromosome maintenance; ATM, ataxia telangiectasia-mutated; ATR, ATM-Rad3-related; CDK2, cyclin-dependent kinase 2; CHK, checkpoint kinase; HU, hydroxyurea; Pipes, 1,4-piperazinediethanesulfonic acid; aa, amino acid; pT, phospho-T. 
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ACKNOWLEDGMENTS
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We thank Jerard Hurwitz for critical reading of this manuscript and discussion, Kumiko Shimizu for technical assistance, Hiroshi Kimura for providing anti-MCM4 antibodies, and Hiroshi Nojima for providing human MCM4, -6, and -7 cDNA.
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