From the Department of Biological Sciences, Columbia University, New York, New York 10027
Received for publication, December 26, 2002
, and in revised form, March 19, 2003.
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ABSTRACT |
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INTRODUCTION |
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The ATM pathway itself is functionally related to DNA damage checkpoints in both budding and fission yeast. In fission yeast, as yet unidentified DNA damage sensor proteins may signal directly or indirectly via downstream kinases or adaptor proteins to the homologous mediator kinases Rad3 and Tel1, which in turn regulate through phosphorylation two effector kinases Cds1 and Chk1 (8). A key target for these kinases is the Cdc25 dual specificity phosphatase that in unstressed cycling cells removes repressing phosphates from the cyclin-dependent kinase Cdc2 and thereby allows it to promote passage through G2/M (reviewed in Ref. 9). When the human homologues of Chk1 or Cds1 were identified and cloned, it became clear that they could phosphorylate different members of the human Cdc25 family (10, 11, 12, 13, 14). Phosphorylation of human Cdc25C at Ser216 leads to its inactivation by 14-3-3-mediated translocation to the cytoplasm (15, 16). There are a number of lines of evidence showing that in human cells ATM is upstream of Chk2. Perhaps the most compelling of these are observations that ATM phosphorylates Chk2 at Thr68 in vitro and that ionizing radiation leads to Chk2 phosphorylation at Thr68 and its subsequent activation in wild type but not ATM null cells (17, 18, 19).
The relationship between the ATM pathway and Chk1 is less well understood.
It is currently believed that Chk1 kinase is downstream of ATR
(ataxia-telangiectasia and Rad3-related kinase), another member of the
phosphatidylinositol 3-kinase family
(20,
21,
22). Although it is possible
to generate cells and animals lacking ATM and Chk2, deletion of ATR or Chk1
causes early embryonic lethal events
(20,
23,
24). More recently, homozygous
deletion of Chk1 in the B cell lymphoma line, DT40, revealed that this kinase
is essential for G2/M arrest and that its loss decreases survival
after irradiation
(25).
Upon various forms of cellular stress, p53 becomes phosphorylated at a number of sites within its N and C termini (reviewed in Ref. 26). Phosphorylation of p53 at N-terminal sites such as Ser15, Thr18, Ser20, and Ser37 within the vicinity of the region where it interacts with Mdm2 can disrupt its interaction with Mdm2 in vitro (27, 28, 29, 30, 31) and may thereby allow for p53 stabilization (32, 33). Among the possible sites, Thr18 and Ser20 lie within the region of p53 that interacts directly with Mdm2 (34). Mutation of Ser20 in human p53 was shown to render p53 less well stabilized after DNA damage and more sensitive to down-regulation by Mdm2 (35, 36, 37). By contrast, murine fibroblasts harboring a mutation of the equivalent residue to human Ser20 that changes murine Ser23 to Ala23 are apparently normal in their response to DNA damage (38).
Given that both Chk1 and Chk2 are checkpoint effector kinases, it was not
unexpected that several groups have linked them experimentally with p53. Using
a biochemical fractionation approach to identify Ser20 kinase
activity, we previously discovered that the human homologues of Chk1 and Chk2
could phosphorylate p53 at this site as well as a number of other sites within
the N terminus such as Ser15, Thr18, and
Ser37 along with unidentified sites within other regions of the
protein (39). Moreover,
expression of either Chk1 kinase-defective or Chk1 antisense constructs leads
to diminution of levels of co-transfected p53 protein
(39). In a parallel study
Chehab et al. (30)
reported that Chk2 can phosphorylate Ser20 and that a kinase
defective form of Chk2 prevents stabilization and phosphorylation at
Ser20 of co-transfected p53 after DNA damage. Overexpression of
Chk2 in U2OS cells, which carry wild type p53, augmented G1 arrest
following irradiation. Further supporting a role for Chk2 as being upstream of
p53, Hirao et al.
(40) reported that thymocytes
and fibroblasts generated from Chk2 knock-out mice are defective in
accumulating p53 after but not UV irradiation. Intriguingly, a second
group using mouse embryo-fibroblasts derived from these mice found that even
at low doses of
irradiation, G1 arrest and p21 induction
were intact (41). More
recently, the results from a second independently generated Chk2 null mouse
have indicated that Chk2 loss protects mice from
irradiation-induced
death consistent with diminished apoptosis in several tissues including the
spleen, intestine, and central nervous system and that p53 in these cells is
transcriptionally inactive
(42).
Finally, data from human patients have revealed that a subset of Li-Fraumeni cancer-prone families with wild type p53 has Chk2 germ line mutations (43, 44), and such mutant forms of Chk2 are defective as protein kinases (45, 46). Strikingly, this natural experiment is not completely recapitulated in murine models. Hirao et al. (47) observed no increase in spontaneous tumors in Chk2/ mice, whereas Takai et al. (42) reported preliminary evidence of an increase in lymphoma development by 71 weeks in Chk2/ animals.
Given that there is somewhat contradictory evidence surrounding the
proposed Chk2-p53 connection, we set out to further characterize Chk2 derived
from human tumor cells that have an intact DNA damage response. The goal was
to study Chk2 before and after activation by either irradiation or the
radiomimetic compound neocarzinostatin (NCS). To our surprise, the results
from both biochemical and short interfering RNA (siRNA) experiments argue
against a role for Chk2 in DNA damage-mediated stabilization of p53 in cancer
cells following
radiation or similar stimuli. We discuss the basis for
the differences between our present results and those that have been
previously published, including our own.
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EXPERIMENTAL PROCEDURES |
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Purification of ProteinsWhere indicated, the cells were treated with a radiomimetic compound NCS (500 ng/ml) (Kayaku Co., Tokyo, Japan) for 2 h before purification of HA-Chk2 as described below. Alternately, the cells were irradiated with 14 Gy (using a 137Cs source) and harvested after 2 h for purification of HA-Chk2. Typically, cells in 20 x 140-mm plates were collected and treated with lysis buffer A containing 50 mM Hepes KOH, pH 7.8, 150 mM KCl, 10 mM NaCl, 0.1 mM EDTA, 1.5 mM MgSO4, 1 mM DTT, 0.2% Nonidet P-40, 0.25 mM phenylmethylsulfonyl fluoride, 60 nM okadaic acid, 240 pM cypermethrin, 1 mM NaF, 100 µM NaVO4, and 20% glycerol. The extracts were precleared with 400 µl of protein A conjugated to agarose (Amersham Biosciences) for 4 h at 4 °C and incubated with 100 µl of protein A cross-linked with anti-HA antibody for 12 h at 4 °C. The beads were collected in a disposable column and extensively washed with lysis buffer a containing 20 mM Hepes KOH, pH 7.8 (15 x 1 ml). The proteins were eluted with 100 µg/ml of HA peptide (SynPep, Dublin, CA) and then dialyzed against buffer B containing 20 mM Tris-HCl, pH 8.0, 100 mM KCl, 0.1 mM EDTA, 1 mM DTT, and 20% glycerol. C-terminally FLAG-tagged wild type and mutant (D347A) Chk2 (Chk2-FLAG) mutant proteins were immunopurified from recombinant baculovirus infected sf-9 insect cells. Typically, 20 x 140-mm plates were collected and treated with the buffer. The extracts collected after centrifugation at 14,000 x g at 4 °C for 30 min were incubated with 0.25 ml of anti-FLAG antibody conjugated to agarose (Sigma). The beads were collected in a 5-ml syringe and washed with lysis buffer A. The proteins were eluted with 100 µg of FLAG peptide (Sigma) and dialyzed against buffer B. Wild type and kinase-defective mutant (D130A) GST-Chk1 proteins were purified from baculovirus-infected insect cells as follows. The cells were incubated with lysis buffer A, and the extracts were collected with 0.5 ml of glutathione-Sepharose 4BL beads (Amersham Biosciences). GST-Chk1 proteins were eluted with 10 mM glutathione after washing away any unbound protein with lysis buffer A and then dialyzed as described above with buffer B.
The plasmid encoding GST-Cdc25C (200256) was kindly provided by Dr.
Junjie Chen. GST fusion proteins, GST-Cdc25C (200256), GST-p53
(182), GST-p53 (97363), and GST-p53 (WT) were expressed in
Escherichia coli BL21 cells after induction with
isopropyl--D-thiogalactoside for 2.5 h (final concentration,
1 mM)at20 °C. The proteins were purified by binding to
glutathione-Sepharose 4BL beads in lysis buffer A followed by elution with 10
mM of glutathione and dialyzed as described above. His-p53 (WT) was
purified as described by Zhou et al.
(48).
In Vitro Kinase Assays and Western BlottingTypically
520 ng of kinase was incubated with 0.14 µg of GST fusion
protein substrates. The reaction mixtures were incubated at 30 °C for 30
min in 20 µl of Buffer C containing 20 mM Hepes KOH, pH 7.8, 100
mM KCl, 10 mM MgCl2, 1 mM DTT, 60
nM okadaic acids, 240 pM Cypermethrin, 1 mM
NaF, 100 µM NaVO4, and 100 µM ATP
supplemented with 1 µCi of [-32P]ATP. The reactions were
terminated by adding 20 µl of SDS-PAGE sample loading buffer. The proteins
were separated by SDS-PAGE, transferred to nitrocellulose, and subsequently
identified and quantitated by immunoblotting with the appropriate antibodies.
The radiolabeled proteins were visualized with autoradiography and quantitated
with PhosphorImager (Molecular Dynamics). The antibodies were obtained as
follows: anti-GST and anti-FLAG (M2) were from Sigma; anti-HA was from Covance
(Princeton, NJ); and anti-His was from Santa Cruz Biotechnology (Santa Cruz,
CA).
Immunoprecipitation Kinase AssaysHCT 116 parental cells in 4 x 140-mm plates were collected and treated with lysis buffer A as described above. The extracts were incubated with 50 µl of agarose beads conjugated with protein A (Amersham Biosciences) and 2 µg of anti-Chk2 antibody (Santa Cruz Biotechnology) for 4 h at 4 °C. The beads were washed with buffer A (15 x 0.5 ml). The indicated amount of beads were incubated with GST-fused substrates in kinase buffer C, and the data were analyzed as described above.
Phosphorylation of p53 by DNA-PKGST-p53 (182) (10 µg) was incubated with DNA-PK (100 ng) in buffer containing 25 mM Hepes, pH 7.9, 50 mM KCl, 10 mM MgCl2, 20% glycerol, 1 mM DTT, 100 µM ATP, and 10 µg/ml of DNA fragments generated from HpaII-digested pBlue-script. Purified DNA-PK was a generous gift of D. Chan (Lawrence Berkeley National Laboratory, Berkley, CA). The mixtures were incubated for 4 h at 30 °C. Phosphorylation at Ser15 was confirmed by separating the reaction mixture on 10% SDS-PAGE, transferring to nitrocellulose, and immunoblotting with anti-Ser(P)15-specific antibody (Cell Signaling, Beverly, MA). The prephosphorylated GST-p53 was purified by binding to glutathione-Sepharose 4CL beads as described above.
RNA InterferencesiRNA duplexes were synthesized by Xeragon Oligoribonucleotides (Huntsville, AL). The luciferase control sequence has been described previously (49). The sequences of the Chk1 oligonucleotides were: 5'-GAAGCAGUCGCAGUGAAGATT-3' and 5'-UCUUCACUGCGACUGCUUCTT-3'. The sequences of the Chk2 oligonucleotides were: 5'-GAACCUGAGGACCAAGAAC-3' and 5'-GUUCUUGGUCCUCAGGUUC-3'. The cells were transfected twice 24 h apart with 1.68 µg of the indicated siRNA duplex using Lipo-fectAMINE 2000 (Invitrogen). The cells that were untreated or treated with 500 ng/ml NCS for the indicated time periods were lysed in TEGN buffer (10 mM Tris, pH 7.5, 1 mM EDTA, 10% glycerol, 0.5% Nonidet P-40, 400 mM NaCl, 1 mM DTT, 0.5 mM phenylmethylsulfonyl fluoride, and protease inhibitor mixture) 72 h after the first transfection. Chk1 was detected with a mouse monoclonal antibody (Santa Cruz Biotechnology), and Chk2 was detected with a rabbit polyclonal antibody (ProSci Inc., Poway, CA). p53 was detected using a mixture of monoclonal antibodies DO-1 and 1801. Protein loading was estimated using an anti-actin polyclonal antibody (Sigma). -Cdc25CS216 and p53S20 antibodies (Cell Signaling) phospho-specific antibodies were used. p53 transcriptional targets were detected using anti-p21 (Ab-1) and anti-HDM2 (Ab-1) (Oncogene Research, San Diego, CA) and anti-p53-induced gene 3 (kindly provided by D. Hill, Oncogene Research Products, Cambridge, MA) antibodies.
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RESULTS |
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A commonly used inducer of DNA strand breaks is irradiation, and so
we performed a similar experiment comparing HA-Chk2 from
irradiated or
unirradiated HCT116 cells (Fig.
1D). The limitation in this case was that it was not
possible to rapidly irradiate large quantities of these cells with ease, and
thus smaller amounts of Chk2 were used. Nevertheless the results were
essentially the same as with NCS. HA-Chk2 activity toward Cdc25C was
significantly increased after
irradiation, whereas that toward p53 was
not detectably affected by irradiation. In this experiment we tested Cdc25C
and p53 alone as well as together to demonstrate that the lack of increased
phosphorylation of p53 after DNA damage is not due to competition with Cdc25C
within the same reaction mixture for available kinase, a conclusion further
supported by experiments shown below. Control purification from extracts of
parental HCT116 cells revealed no contaminating kinases that were activated
after
irradiation to phosphorylate p53 or Cdc25C.
Previously we used recombinant baculovirus-expressed Chk2 tagged with the
FLAG epitope at its C terminus (Chk2-FLAG) to phosphorylate p53. We wished to
compare the relative ability of this source of enzyme to phosphorylate Cdc25C
and p53 to ensure that the HA tag at the N terminus of Chk2 isolated from
HCT116 cells was not affecting the ability of Chk2 to phosphorylate p53. Using
similar constructs as substrates, we found that baculovirus-derived Chk2-FLAG
is in fact dramatically more efficient at phosphorylating Cdc25C than p53
(Fig. 1E).
Phosphorimaging analysis of the data shown in
Fig. 1E indicated that
Chk2-FLAG displayed up to a 50-fold greater ability to phosphorylate Cdc25C
than p53 over the concentrations used. Importantly, Chk2-FLAG from
baculovirus-infected insect cells strongly resembles HA-Chk2 from NCS-treated
cells (51). First, like
HA-Chk2 isolated from irradiated or NCS-treated cells, Chk2-FLAG is
phosphorylated at Thr68 (the ATM kinase site that is required for
Chk2 activation). Second, Chk2-FLAG has virtually identical specific activity
toward Cdc25C as does HA-Chk2 isolated from NCS-treated HCT116 cells. Thus,
two different sources of activated Chk2 are each dramatically more effective
in phosphorylating Cdc25C than p53.
The possibility existed that endogenously expressed untagged Chk2 might behave differently than either stably expressed exogenous HA-Chk2 or baculovirus-derived Chk2-FLAG. To address this we examined the activity of Chk2 from the parental line of HCT116 cells using an anti-Chk2 monoclonal antibody. Consistent with our results using tagged forms of Chk2, endogenous Chk2 was far more active in phosphorylating Cdc25C than p53 and was stimulated by DNA damage to phosphorylate the former but not the latter (Fig. 1F). We considered the possibility that Chk2 may be activated to phosphorylate p53 at time points other than the single time point used thus far (i.e. 2 h after NCS treatment). HA-Chk2 was purified from HCT116 cells after exposure to NCS for various times and tested for its activity toward Cdc25C and full-length p53 at each time point. Increased activity of HA-Chk2 was detected as early as 30 min after treatment with NCS, and both then and at all time points thereafter, HA-Chk2 remained activated with respect to phosphorylation of Cdc25C but not of p53 (Fig. 1G). Similar results were obtained using a N-terminal fragment of p53 (data not shown).
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In the kinase assays shown in Fig. 1A,1G a GST-tagged N-terminal fragment of p53 was used as a substrate. Shieh et al. (39) had provided evidence that there are sites that are phosphorylated by Chk2 in other regions of the p53 protein. Furthermore, we previously demonstrated that p53 oligomerization is required for its efficient phosphorylation by Chk1 and Chk2 in vitro as well as its ability to be phosphorylated at N-terminal sites in vivo (39, 52). To determine whether the lack of tetramerization or distal phosphorylation sites in GST-p53 (182) explains the failure of phosphorylation by NCS-activated Chk2, tetrameric versions of p53 (full length or p53 lacking amino acids 196) were tested for their ability to serve as substrates for HA-Chk2 from untreated or NCS-treated cells (Fig. 2). Although NCS-activated HA-Chk2 was again far more effective in phosphorylating Cdc25C than HA-Chk2 from untreated cells, there was no discernable stimulation of its ability to phosphorylate two different tagged forms of full-length p53 or GST-p53. Note that bacterially expressed His-p53 forms tetramers (48), indicating that the ability of Chk2 to phosphorylate p53 does not result from a lack of oligomerization. This reinforces the conclusion that Chk2 cannot be activated to phosphorylate p53. Additionally, the result with His-tagged p53 shows that the GST tag is unlikely to interfere with Chk-2 phosphorylation of p53. It should also be mentioned that these results are not unique to HCT116 cells; epitope-tagged Chk2 similarly isolated from a clonally derived HeLa cell line is also very weak in phosphorylating p53 and is not stimulated by NCS treatment.2 Thus, with or without activation by DNA damage, Chk2 from HCT116 cells displays only its basal phosphorylation activity toward p53.
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Prephosphorylating p53 Does Not Make It a Better Substrate for Chk2ATM can phosphorylate p53 at Ser15, and its ability to do so is increased when cells are irradiated or treated with NCS (7). Because ATM is upstream of Chk2, we considered the possibility that p53 needs to be first phosphorylated at Ser15 to be primed for phosphorylation at other N-terminal sites. A precedent for this is the observation that prephosphorylation of Ser15 is required for Thr18 phosphorylation by casein kinase 1 (31, 53). To test this we prephosphorylated p53 with the DNA-PK. This enzyme was used because it has not been possible to obtain a similarly purified and active preparation of ATM kinase in our laboratory. p53 was efficiently phosphorylated by DNA-PK at Ser15 as determined both by reactivity with an anti-Ser(P)15 antibody and an upward gel mobility shift after SDS-PAGE (Fig. 3A, top and bottom panels, compare lanes 14 with lane 5). Nevertheless, Chk2-FLAG showed no increase in its ability to phosphorylate p53 that had been prephosphorylated by DNA-PK (Fig. 3B, compare lanes 14 and lanes 58). This experiment argues against the possibility that p53 requires priming phosphorylation at Ser15 prior to Chk2 phosphorylation.
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We then took advantage of our earlier observation that Chk1 can also phosphorylate p53 at a number of N-terminal sites to assay for any synergy between the two human Chk kinases (39). The possibility was considered that weak p53 phosphorylation by Chk2 could be a priming event for phosphorylation by Chk1 (or vice versa). In addition, it was of interest to see whether inter-Chk activating phosphorylation(s) can be demonstrated and are required for efficient phosphorylation of p53. Cdc25C and p53 were incubated with baculovirally expressed wild type or kinase-defective forms of tagged Chk1 and/or Chk2 proteins. Purity of proteins used are shown in the silver-stained gel in Fig. 4A. First, we found that, similar to Chk2, catalytic amounts of Chk1 are able to phosphorylate Cdc25C (200256) but not the N terminus of p53 (Fig. 4B, lane 1). Second, extending observations with short peptides (54), Chk1 showed greater specific activity toward Cdc25C than did Chk2 (Fig. 4B, compare lanes 1 and 7). Third, incubation of Chk1 and Chk2 with p53 ruled out any requirement for both Chk kinases in phosphorylating p53 (Fig. 4B, lane 2). Finally, to explore the possibility of inter-Chk1 and Chk2 phosphorylation, we incubated wild type Chk1 with kinase-inactive Chk2 (11) or wild type Chk2 with kinase mutant Chk1 (10) (Fig. 4B, lanes 3 and 5) and found that neither Chk1 nor Chk2 can phosphorylate each other.
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Taken together our data show that Chk1 and Chk2 behave very differently in in vitro kinase reactions toward two of their reported substrates p53 and Cdc25C. Although DNA damage greatly increases the activity of Chk2 toward Cdc25C, no similar augmentation of activity is observed on p53, as would be expected of checkpoint effector kinases functioning to trigger p53.
p53 Is Stabilized by DNA Damage in Cells Lacking Normal Physiological
Levels of Chk1 and Chk2Given our surprising observation that the
p53 specific activity of Chk2 does not rise after checkpoint activation, a
number of scenarios might be invoked to explain how Chk2 regulates p53. For
example activation of an intermediary kinase, substrate recruitment by
phosphorylation of an adaptor molecule, or other possibilities could explain
our biochemical results. However, all of these ideas would predict that Chk2
controls p53 activation in vivo regardless of its performance in
vitro. To test this hypothesis, we used 21-nt siRNA duplexes to reduce
Chk1 and Chk2 protein levels in cancer cell lines
(49). Transfection of HCT116
cells with anti-Chk1, anti-Chk2, or both siRNAs but not the control
anti-luciferase siRNA resulted in specific and significant down-regulation of
each kinase. (Fig. 5, compare
lanes 13 and 46 for Chk1 and lanes
13 and 79 for Chk2). We estimate that Chk2 was
generally reduced by 6075% and Chk1 by over 9098% by their
respective siRNAs. The relatively greater decrease in Chk1 may be because it
is a less stable protein (55).
Because Chk2 protein was incompletely ablated, we examined the impact of
siRNA-induced Chk2 down-regulation on induction of Cdc25C phosphorylation at
Ser216 using a phosphospecific antibody. NCS caused an increase in
reactivity with the anti-Ser(P)216 antibody
(Fig. 5, lanes
13) that was unaffected by nearly undetectable levels of Chk1
(lanes 46). However, reduction in Chk2 protein, although
incomplete, was sufficient to inhibit increased phosphorylation of
Ser216 on Cdc25C (Fig.
5, lanes 79). Transfection with the
anti-luciferase or anti-Chk kinase siRNAs was not associated with changes in
cell cycle distribution or apoptosis (data not shown). Because siRNA
transfection was both effective and nonlethal, we went on to determine the
impact of reduced Chk1 and Chk2 on p53 protein accumulation and
transcriptional activation by p53. HCT116 cells transfected with the indicated
siRNAs were treated with NCS for 0.5 or 3 h
(Fig. 6A, top left
panel). p53 protein levels were increased after NCS treatment by 3 h, and
transfection of the luciferase control siRNA did not prevent p53 induction.
However, down-regulation of Chk1, Chk2, or even both kinases simultaneously
had no effect on p53 stabilization. We next examined longer time points, 5 and
15 h, following NCS treatment before assessing p53 levels
(Fig. 6B, right
panels). Again, very low levels of Chk2 and virtual elimination of Chk1,
either individually or both proteins together, had no effect on induction of
p53 after NCS treatment. (Note that the anti-Chk2 polyclonal antibody used in
these studies has a reduced ability to recognize Chk2 after NCS treatment
presumably because the kinase becomes highly phosphorylated as a result of NCS
treatment. This phenomenon has been noted with other Chk2 antisera
(11).)
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Interestingly, down-regulation of Chk1 and Chk2 without drug treatment stabilized p53 to some extent, suggesting that cells may sense a loss of Chk1 or Chk2 as a stress signal. However, this stress did not compromise p53 stabilization following NCS treatment because peak levels achieved in control versus Chk1 and/or Chk2 siRNA transfected cells were comparable or were even slightly increased by down-regulation of the Chk kinases (Fig. 6A, left and right histograms).
p53 mediates its checkpoint function primarily through transcriptional activation. It was of interest to determine whether p53 can induce its transcriptional targets when the checkpoint kinases were reduced or depleted by siRNA (Fig. 6). Three well validated targets of p53 (p21, Mdm2, and p53-induced gene 3) were examined by immunoblotting in parallel with p53, Chk1, and Chk2. Within 30 min after NCS treatment and prior to p53 stabilization, there was a consistent slight decrease in the levels of detectable p21 and Mdm2 protein regardless of the siRNA that was introduced into the cells. Although the reason for this is not clear, by 3 h after the addition of NCS concomitant with increased p53, a modest increase in accumulation of p21 was observed (Fig. 6A, left p21 panel) that became more pronounced with longer intervals after drug treatment (Fig. 6B, right p21 panel). Hdm2 and p53-induced gene 3 protein levels were also increased upon stabilization of p53 regardless of the levels of Chk1 and Chk2. Note as well that Jallepalli et al. (61) have determined that p53 induction as well as cell cycle arrest and apoptosis after DNA damage are normal in HCT116 cells from which both Chk2 alleles have been deleted.
Because Chk2 is thought to be responsible for phosphorylation of p53 on
Ser20, we sought to directly examine the effect of Chk2
down-regulation on induction of phosphorylation at that site. To be able to
assess Ser20 phosphorylation independently of changes in p53
protein levels, we took advantage of an earlier observation that mutant p53 in
HT-29 human colorectal carcinoma cells is phosphorylated but not stabilized
after DNA damage (52). HT-29
cells were transfected with luciferase or Chk2 siRNA as above and then
collected 30 min after exposure to 10 Gy of irradiation
(Fig. 6C). Despite
markedly reduced levels of Chk2 protein and consistent with the lack of an
effect on p53 stabilization, induction of Ser20 phosphorylation was
not affected by down-regulation of Chk2.
One advantage of siRNA is the ability to test the response of different cell lines and thereby alleviate concerns that a result is relegated to a single cell line. To expand our analysis of Chk1 and Chk2 in the p53 DNA damage response, we examined the response of p53 to Chk kinase reduction in MCF-7 (breast carcinoma) and RKO (colon carcinoma) cell lines. MCF-7 cells were transfected with the anti-Chk siRNAs and subsequently exposed to NCS for 0.5 or 2.5 h and then analyzed for p53 stabilization. In these cells, p53 stabilization could be detected as early as 0.5 h after NCS treatment. As with HCT116 cells, in the absence of DNA damage, down-regulation of Chk1 and/or Chk2 resulted in slight stabilization of p53. Nevertheless, p53 protein was considerably further increased after treatment with NCS and reached similar peak levels in control versus Chk siRNA transfected cells (Fig. 7A, top and middle panels). Transcriptional activation was also apparently unimpaired as Hdm2 protein was induced to comparable levels regardless of Chk kinase levels. Similarly, RKO cells showed uncompromised induction of p53 following NCS treatment despite down-regulation of one or both Chk kinases (Fig. 7B).
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These data indicate that down-regulation of the Chk kinases to levels far below normal in some human tumor cell lines has no impact on stabilization of p53 or most likely of p53 function after treatment with a radiomimetic compound, thus arguing against indirect regulation of the p53 pathway by the Chk kinases. These observations in combination with our biochemical data lead us to conclude that under certain conditions Chk1 and Chk2 are improbable central regulators of the p53 pathway.
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DISCUSSION |
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How do we reconcile our results with those previously published showing that recombinant Chk2 phosphorylates p53 and abrogation of Chk2 function disables the p53 response? With respect to the first, one must consider that substrate specificity of activated kinases is rendered not only by identity of the residues being phosphorylated but also optimal interaction between surrounding residues in the substrate and in the active site of the kinase. Using peptide libraries to search for substrate motifs for Chk1 or Chk2 phosphorylation, it was found that both kinases display strong preference for the sequences surrounding Cdc25C and Cdc25A sites and virtually none for the Ser20 region of p53 (54, 56). This is consistent with the fact that the residues surrounding p53 Ser20 bear no resemblance to the Chk2 sites in Cdc25C and other reported Chk2 targets including BRCA1 (54). Although short peptides might not have provided the same information as a larger protein, our data clearly agree with their findings. In our experiments, Chk2 favored Cdc25C over p53 by a factor of 50-fold. Our previous experiments (39) and those of Chehab et al. (30) showing phosphorylation of p53 by these kinases used stoichiometric amounts of substrates and kinases, an experimental condition where substrate specificity of kinases cannot be properly measured. Although Chk2 can interact with p53 (57),3 this association is not sufficient to allow Chk2 to phosphorylate p53 comparably with Cdc25C.
To examine the significance of our biological observations in vivo, we used siRNA to down-regulate Chk1 and Chk2 in tumor cell lines. Although Chk1 was very efficiently ablated, in our experiments Chk2 could only be reduced by 6070%. Nevertheless, this amount of down-regulation was sufficient to prevent DNA damage-induced phosphorylation of Cdc25C at Ser216 but did not effect p53 activation and function. Admittedly, this is an imperfect control given the likelihood that distinct regulatory mechanisms exist for the various substrates of a given kinase. Arguing against such a criticism in this case is that in vitro Cdc25C is a much stronger substrate than p53, suggesting that Cdc25C should have a higher ablation effect threshold in vivo than p53. We do not observe such a correlation. Nevertheless in RNAi experiments, aphenotypic observations in the context of incomplete knock-down leave open the possibility that the remaining protein is sufficient to mediate function. These concerns are for the most part alleviated by the data presented by Jallepalli et al. (61) that homozygous deletion of Chk2 does not have an impact on p53 function. Moreover, introduction of Chk1 siRNA into Chk2/ cells revealed no diminution of p53 accumulation or function.4
Previous studies examining Chk2 and p53 showed that introduction of a dominant negative form of this kinase (30) led to failure of U2OS cells to stabilize or phosphorylate endogenous p53 at Ser20. It can be argued that introduction of a dominant negative form of Chk2 might have effects in cells in addition to Chk2 expression. In fact, reports indicate that some tumor-derived mutants of Chk2 do not act in a dominant negative fashion when expressed with wild type Chk2 (45, 46). In our previous study (39) we showed that co-transfection of antisense Chk1 with p53 into H1299 cells led to reduced levels of p53 when compared with its being co-transfected with vector alone. Although this is not consistent with our results herein, it is possible that the overexpression of transfected p53 requires Chk1 regulation by a mechanism that is not yet clear.
Regarding the results with Chk2 knock-out mouse cells, the situation is
complicated by the fact that there are inconsistencies among the different
reports that have been published. Whereas Hirao et al.
(40) reported a failure of p53
stabilization and p21 induction in
Chk2/ cells, Jack et
al. (41) using the same
cells demonstrated induction of p21 after irradiation. In a follow-up study
Hirao et al. (47)
also described normal accumulation of p21 mRNA. These
Chk2/ mice exhibit a subtle
defect in G1 arrest in which incorporation of bromodeoxyuridine in
epidermal cells was unaffected by irradiation in
Chk2/ animals, but closer
examination of mouse embryo fibroblasts and thymocytes lacking Chk2 found this
defect only at low (5 Gy) doses of IR, whereas arrest was comparable at higher
doses (10 Gy).
The generation of a second Chk2 null mouse further complicates the picture (42). In that study Chk2/ cells failed to show an increase in cells with a G1 DNA content following irradiation, indicating deficiencies in this p53 dependent checkpoint. In sharp contrast to Hirao et al. (40), stabilization of p53 was only partially affected by loss of Chk2 (5070% of normal levels), but here p53 was apparently completely transcriptionally inactive. However, human p53 introduced by adenovirus into these Chk2/ cells was phosphorylated normally at Ser20 following DNA damage.
In summary, the ability of p53 to activate cell cycle arrest through p21 in Chk2 null mouse embryo fibroblasts is unclear, and in fact the role of Chk2 in cell cycle checkpoints at both G1/S and G2/M transitions remains to be clarified (40, 41, 42, 47). What is far more consistent is that in mice Chk2 regulates apoptotic processes (40, 42, 47). Nevertheless, the resistance to apoptosis in Chk2/ cells has not been rigorously demonstrated to be p53-dependent in all cases. Embryonic stem cells from wild type and Chk2 null mice were equally sensitive to a number of DNA-damaging agents, whereas thymocytes lacking Chk2 were not, despite a similar defect in p53 stabilization in both cell types (40, 42). Furthermore, a recent report links Chk2 and the promyelocytic leukemia protein in the induction of p53-independent apoptosis (58). Once the situation with mouse fibroblasts as well as other cell types becomes clarified, it will hopefully be possible to explain the differences between these results and ours presented here. Perhaps the discrepancy simply represents inherent differences between mouse and human cells. Alternatively, these may not be discrepancies at all but rather point to possible and intriguing consequences of the transformation process in which the requirement for Chk2 by p53 is lost. The finding that families with germ line mutations in p53 or Chk2 develop a similar spectrum of tumors suggested that loss of p53 or Chk2 is functionally synonymous (43). However, co-existent p53 and Chk2 mutations have been reported in sporadic cancers as well, including the commonly used colon cancer cell line HCT-15 (43, 59, 60). Our data implicating p53 and Chk2 in distinct pathways provide a possible explanation for these observations.
Our results pose new questions. First, because the data linking Chk2 and apoptosis is quite compelling, whereas our data as well as that of Jallepelli et al. (61) suggest that the role of Chk2 as a tumor suppressor is not centered on p53, how does Chk2 regulate cell death? Second, and just as important, are the consequences of our findings in understanding p53 function. Disruption of p53 function is a frequent characteristic of tumor development that can occur at the level of p53 mutation but also through the interruption of upstream and downstream factors. Therefore, detailed insight into the mechanisms of p53 activation will deepen our knowledge of cancer progression as well as treatment response. Given that both fission and budding yeast do not have a p53 homologue, the observation that p53 had been evolutionarily integrated into the conserved DNA damage response via Chk2 was an appealing hypothesis. Yet, if p53 is not a physiologically relevant substrate of Chk2 or most likely Chk1, the challenge will be to identify protein kinases that are activated by DNA damage to phosphorylate residues such as Thr18 or Ser20. An outline for future identification of those factors mediating p53 activation is now in place, and exciting new findings in these areas are anticipated.
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FOOTNOTES |
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These authors contributed equally to this work.
To whom correspondence should be addressed. Tel.: 212-854-5277; Fax:
212-865-8246; E-mail:
clp3{at}columbia.edu.
1 The abbreviations used are: Mdm2, murine double minute 2; ATM, Ataxia
telangiectasia-mutated protein; Chk1, Checkpoint Kinase 1; Chk2, Checkpoint
Kinase 2; NCS, neocarzinostatin; GST, glutathione S-transferase;
siRNA, short interfering RNA; HA, hemagglutinin; Gy, gray; DTT,
dithiothreitol; WT, wild type; DNA-PK, DNA-activated protein kinase.
2 J. Ahn, J. Zhou, and C. Prives, unpublished data.
3 J. Ahn and C. Prives, unpublished data.
4 M. Urist, F. Bunz, and C. Prives, unpublished observations.
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ACKNOWLEDGMENTS |
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REFERENCES |
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