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Molecular and Cellular Biology, April 1999, p. 2828-2834, Vol. 19, No. 4
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Requirement of ATM in Phosphorylation of the Human
p53 Protein at Serine 15 following DNA Double-Strand Breaks
Kazumi
Nakagawa,1
Yoichi
Taya,2
Katsuyuki
Tamai,3 and
Masaru
Yamaizumi1,*
Institute of Molecular Embryology and
Genetics, Kumamoto University School of Medicine, Kumamoto
862-0976,1 National Cancer Center
Research Institute, Chuo-ku, Tokyo
104-0045,2 and Ina Laboratory, MBL Co.
Ltd., Ina, Nagano 396,3 Japan
Received 17 September 1998/Returned for modification 3 November
1998/Accepted 7 January 1999
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ABSTRACT |
Microinjection of the restriction endonuclease HaeIII, which causes
DNA double-strand breaks with blunt ends, induces nuclear accumulation
of p53 protein in normal and xeroderma pigmentosum (XP) primary
fibroblasts. In contrast, this induction of p53 accumulation is not
observed in ataxia telangiectasia (AT) fibroblasts. HaeIII-induced p53
protein in normal fibroblasts is phosphorylated at serine 15, as
determined by immunostaining with an antibody specific for
phosphorylated serine 15 of p53. This phosphorylation correlates well
with p53 accumulation. Treatment with lactacystin (an inhibitor of the
proteasome) or heat shock leads to similar levels of p53 accumulation
in normal and AT fibroblasts, but the p53 protein lacks a
phosphorylated serine 15. Following microinjection of HaeIII into
lactacystin-treated normal fibroblasts, lactacystin-induced p53 protein
is phosphorylated at serine 15 and stabilized even in the presence of
cycloheximide. However, neither stabilization nor phosphorylation at
serine 15 is observed in AT fibroblasts under the same conditions.
These results indicate the significance of serine 15 phosphorylation
for p53 stabilization after DNA double-strand breaks and an absolute
requirement for ATM in this phosphorylation process.
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INTRODUCTION |
Upon various types of cellular
stresses, protein levels of the tumor suppressor p53 increase rapidly,
mainly by posttranslational mechanisms. The elevation of p53 in turn
induces inhibition of cell cycle progression and/or apoptosis
(17). This system is important for the maintenance of the
integrity of genetic information and for elimination of abnormal cells.
Defects in this system result in a high incidence of tumor progression
(6) or in abnormal development (25). The stresses
which induce the accumulation of p53 include genotoxic radiation (X
ray, 
ray, UV, etc.), genotoxic drugs (8), inhibitors of
DNA replication and transcription (32), and cellular
stresses (9, 30) (heat shock, osmotic shock, hypoxia, etc.).
How these stresses are sensed by cells and how the signals are
transduced to effector molecules in cells are subjects of great interest.
Ataxia telangiectasia (AT) is an autosomal recessive disorder which is
characterized by radiosensitivity of the affected individual. Patients
suffering from AT often develop neoplasia, and thus a link between
radiosensitivity and predisposition to develop cancer is suspected. AT
cells are sensitive to ionizing radiation (IR) and show radioresistant
DNA synthesis after IR. The gene responsible for AT has recently been
identified (ATM), but its role and function in radiosensitivity and
predisposition to develop cancer are not known. The AT gene encodes a
protein whose homology suggest it to be a member of the
phosphatidylinositol 3-kinase family (27). In AT cells, or
cells derived from ATM gene knockout mice, p53 accumulation after IR is
blunted or delayed compared with that of normal cells (15).
However, the p53 responses of AT cells against other genotoxic agents
such as UV are normal (4). For this reason, ATM has been
suggested to be involved in the specific signaling pathway evoked by
X-ray-type DNA-damaging agents.
p53 is degraded rapidly by the proteasome through a
ubiquitination-dependent pathway. In this process, Mdm2 plays a crucial role. Mdm2 was found as a protein associating with p53. Expression of
the mdm2 gene is controlled by p53 protein levels.
Interestingly, Mdm2 regulates both the transactivator activity
(23) and stability (18) of p53 by direct
association. As a consequence of the Mdm2-p53 interaction,
intracellular p53 levels are maintained at a low level throughout the
cell cycle (10). It is reported that Mdm2 has a ubiquitin
ligase activity for p53 via the ubiquitin-conjugating enzyme E2
(11). Treatment of normal cells with specific inhibitors of
the proteasome results in the accumulation of p53 protein
(21), indicating the importance of complex formation between
p53 and Mdm2 for p53 turnover. It is reported that phosphorylation of serine 15 of p53 is detected with a phosphoserine-specific antibody in
vivo after genotoxic treatments including or UV irradiation and
that phosphorylation at this site results in inhibition of p53-Mdm2
complex formation (28).
DNA-specific protein kinase (DNA-PK), another member of the
phosphatidylinositol 3-kinase family, has been reported to
phosphorylate p53 at serines 15 and 37 in vitro (19). Its
activity is regulated by the Ku heterodimer protein complex when it is
bound to the ends of severed DNA strands. Thus, this kinase is a
candidate for sensing DNA strand breaks. Recently, it is also reported
that the phosphorylation of serine 15 of p53 is impaired in AT cells after irradiation (29). These results suggest the
importance of ATM in the phosphorylation of this site, but it is
uncertain whether DNA-PK is also involved in the phosphorylation
process following DNA double-strand breaks and whether serine 15 phosphorylation is also involved in the accumulation of p53 protein
after other cellular stresses.
To answer these questions, we have established an assay system to
assess the contribution of ATM to the p53 response induced by DNA
double-strand breaks. In this system, we microinjected restriction endonucleases into normal and AT cells to introduce DNA
double-strand breaks and determined phosphorylation of p53 by
immunostaining with phosphoserine-specific antibodies. We
found that phosphorylation at serine 15 of p53 correlated with p53
stabilization after DNA double-strand breaks and that ATM was essential
for the process.
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MATERIALS AND METHODS |
Cells and treatment.
Mori (12) and Turu are
primary normal human skin fibroblasts. TKO2 and TKB2 are primary
fibroblasts of xeroderma pigmentosum (XP) complementation groups F and
C, respectively. All of these cells were diagnosed and established in
this laboratory. AT2KY (7) and AT10S are primary AT
fibroblasts purchased from the Japan Health Science Foundation (Osaka,
Japan). The cells were cultured in Dulbecco's modified Eagle's medium
supplemented with 10% fetal calf serum, penicillin G (100 U/ml), and
streptomycin (100 µg/ml) in a humidified 5% CO2 incubator.
For X irradiation, cells were cultured in a plastic dish (30 mm in
diameter). Just before irradiation, the medium volume was adjusted to
1.0 ml, and the dish was with X irradiated (Hitachi MBR-1520R) at a
fluence of 0.22 Gy/s with a plastic dish cover. For UV (254 nm)
irradiation, cells were washed once with phosphate-buffered saline
(PBS) and irradiated at a fluence of 0.65 J/m2/s. For
lactacystin (Kyowa, Japan) treatment, the drug was added to the culture
medium at a concentration of 50 µM. For heat shock treatment, cells
were cultured in a plastic dish (30-mm diameter). Just before heat
shock, the medium volume was adjusted to 1.0 ml, and cells were
incubated for 45 min at 43°C in a humidified CO2
incubator. Then the cells were cultured in a humidified CO2 incubator set at 37°C.
Immunostaining.
For immunostaining, fibroblasts were
cultured on glass coverslips for at least 2 days and treated when in
logarithmic growth. After treatment with various kinds of p53 inducers,
cells were fixed for 10 min with 80% methanol at 
10°C. p53
staining was performed as previously described (32).
Briefly, fixed cells were stained for 30 min at room temperature with
an anti-p53 monoclonal antibody (PAb 1801; 1:200 dilution; Calbiochem),
washed with PBS, and then stained for 30 min at room temperature with
fluorescein isothiocyanate (FITC)-conjugated anti-mouse immunoglobulin
G (IgG; 1:100 dilution, Cappel). For staining of phosphorylated serine 15 or 37 of p53, affinity-purified rabbit polyclonal antibody (1:100
dilution of the affinity-purified IgG fraction [0.3 mg/ml]) was used.
Preparation and purification of these phosphoserine-specific antibodies
are described elsewhere (16). Briefly, phosphoserine 15- and
phosphoserine 37-specific antisera were raised against chemically
synthesized, keyhole limpet hemocyanin-conjugated phosphopeptides SVEPPLS(PO3)QETFSDC (amino acids 9 to 21) and
VLSPLPS(PO3)QAMDDLC (amino acids 31 to 43), respectively.
The antisera were affinity purified through columns conjugated with
phosphorylated peptides and unphosphorylated peptides consecutively.
These peptides were also used for antibody blocking experiments in Fig.
4. Fixed cells were stained for 30 min at room temperature with
phosphoserine-specific antibodies, washed with PBS, and stained for 30 min at room temperature with FITC-conjugated anti-rabbit IgG (goat;
1:100 dilution; Cappel). To enhance the intensity of fluorescence,
cells were further stained for 30 min at room temperature with
FITC-conjugated anti-goat IgG (rabbit; 1:100 dilution; Chemicon
International Inc.). For double staining for p53 and phosphorylated
serine 15, fixed cells were first stained with an anti-phosphoserine 15 antibody (rabbit), washed, and then stained with a mixture of anti-p53
monoclonal antibody (mouse) and FITC-conjugated anti-rabbit IgG (goat).
After a wash with PBS, the cells were further stained with a mixture of
FITC-conjugated anti-goat IgG (rabbit) and rhodamine-conjugated anti-mouse IgG (rabbit; Cappel).
Microinjection.
Microinjections with glass needles were
performed as described elsewhere (33). To identify
microinjected cells, cells were plated on glass coverslips on which
small circles were engraved with a diamond knife. Usually, 50 to 100 cells in the small circle were microinjected for analysis. Since we
found in preliminary experiments that both nuclear and cytoplasmic
microinjection of restriction endonucleases induced nuclear
accumulation of p53 protein in normal fibroblasts at similar levels,
endonucleases were microinjected into the cytoplasm throughout this
study. Viability of the microinjected cells was found to be more than
95%. Endonuclease HaeIII was purchased from Takara (Tokyo, Japan) in a
high-concentration (50-U/µl) solution. Just before microinjection,
endonucleases were diluted with an injection buffer (3 mM NaCl, 137 mM
KCl, 8 mM NaH2PO4, 1 mM
KH2PO4, 0.2 mg of bovine serum albumin per ml,
0.02% Triton X-100).
Western blot analysis.
Human fibroblasts were harvested in
trypsin-EDTA, washed with PBS, and then lysed in lysis buffer (1.7%
sodium dodecyl sulfate, 17% glycerol, 0.1 M dithiothreitol, 0.083 M
Tris [pH 6.8]) at a cell concentration of 2.5 × 104
cells/µl. Cell extracts were boiled for 15 min and stored at 80°C
before use. Samples (2.5 × 105 cells per lane) were
analyzed by electrophoresis on a sodium dodecyl sulfate-12.5%
polyacrylamide gel and transferred to polyvinylidene difluoride
membranes (Millipore) by a semidry electroblotter (Bio-Rad). Membranes
were immersed in blotting buffer consisting of 3% nonfat dry milk
(Difco) and 3% fetal calf serum in Tris-buffered saline (TBS; 0.02 M
Tris, 0.1 M NaCl [pH 7.5]), gently shaken for 30 min at room
temperature, and subsequently immunoblotted with a monoclonal antibody
against p53 (PAb 1801; Calbiochem) at a 1:50 dilution or with a rabbit
polyclonal antibody against phosphoserine 15 of p53 at a 1:500
dilution. The membranes were washed three times with TTBS (0.05% Tween
20 in TBS) and then reacted with horseradish peroxidase-conjugated
anti-mouse (sheep) or anti-rabbit (donkey) IgG (Amersham). Membranes
were washed repeatedly with TTBS, and the signal was visualized by an
enhanced chemiluminescence system (Amersham) according to the
manufacturer's protocol.
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RESULTS |
Defects in p53 protein accumulation induced by DNA double-strand
breaks with restriction endonuclease in AT cells.
In normal cells,
p53 protein levels are enhanced by treatment with IR. However, in
addition to DNA strand breaks, IR causes various types of DNA damage,
some of which are not identified, and cellular intoxication due to the
generation of oxygen radicals. Such broad action of IR sometimes causes
unexpected effects in irradiated cells, and makes interpretation of
results difficult. We have systematically examined enzymatic inducers
which incise DNA strands and evoke elevation of p53 protein
levels after introduction. These included DNase I, DNase II, and
various restriction endonucleases (EcoRI, PvuII,
ScaI, and HaeIII). Introduction of
restriction endonucleases into cells via electroporation has been shown
to induce chromosome damage (2) and subsequent p53
accumulation (20, 22). Among the nucleases tested, we
found that restriction endonuclease HaeIII, which causes
blunt-ended DNA double-strand breaks at GGCC, was the strongest
inducer. Microinjection of HaeIII enhanced p53 protein levels in normal
and nucleotide excision repair-defective XP fibroblasts
(complementation groups C and F) as determined by immunostaining (Fig.
1). Since no accumulation of p53 protein
was observed with microinjection of the buffer solution for HaeIII, p53
accumulation by HaeIII was not induced nonspecifically through the
microinjection procedure. p53 accumulation was detected with HaeIII
concentrations ranging from 0.1 to 5 U/µl. Optimal induction was
obtained at a concentration around 1 U/µl. At concentrations above 5 U/µl, the intensity of fluorescence and frequency of p53-stained
cells decreased, possibly due to a toxic effect. Elevation of p53
protein levels were detectable as early as 1 h after
microinjection. Maximal levels were observed first around 2 h and
detected even 16 h after microinjection (Fig. 2A). In sharp contrast, the two AT cell
strains examined in this study showed no p53 protein accumulation even
when incubation times after microinjection of HaeIII were extended to
16 h (Fig. 2B). However, consistent with earlier studies (4,
15, 29), substantial numbers (~30%) of these AT cells became
p53 positive following X-ray treatment (Fig. 2C).
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FIG. 1.
Defective accumulation of p53 protein in AT cells
following DNA double-strand breaks. p53 protein accumulation was
induced by microinjection of restriction endonuclease HaeIII (1 U/µl)
in the indicated primary fibroblasts (see text for descriptions). After
microinjection, cells were cultured for 3 h and stained for p53
protein with anti-p53 monoclonal antibody PAb 1801.
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FIG. 2.
Time course of p53 accumulation after microinjection of
HaeIII into normal and AT fibroblasts. HaeIII (1 U/µl) was
microinjected into either normal (Mori; A) or AT (AT2KY; B)
fibroblasts. (C) AT fibroblasts treated with X-rays (20 Gy). The cells
were cultured for the indicated periods and stained for p53 protein.
The frequency of positive cells was determined as the percentage of
cells showing positive staining. Two independently performed
experiments gave similar results; representative data from one
experiment are shown.
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p53 accumulation induced by HaeIII correlates with phosphorylation
of p53 protein at serine 15.
After treatment with rays or UV
irradiation, p53 protein in established human cell lines with wild-type
p53 alleles is phosphorylated at serine 15 (28, 29).
Phosphorylation of p53 at its N-terminal domain is suspected to
cause a structural change which hampers its interaction with Mdm2
and thus leads to its escape from degradation (28). We
examined histochemically whether phosphorylation at serine 15 took
place in normal fibroblasts after microinjection of HaeIII. A rabbit
polyclonal antibody which specifically recognizes phosphorylated serine
15 of p53 protein was used to assess the levels of p53 phosphorylation.
This antibody has been used for Western blotting analysis elsewhere
(28, 29) and found to be specific for phosphorylated serine
15 of p53. As shown in Fig. 3, when
normal fibroblasts were incubated for 3 h after
microinjection of HaeIII, nuclei of these cells were stained positively
with both an anti-p53 monoclonal antibody and a rabbit antibody
specific for phosphoserine 15 of p53. Similar positive staining of
nuclei for p53 and phosphoserine 15 was observed in normal cells
irradiated with X rays (20 Gy, 3 h). Although more than 90% of
the normal cells treated with lactacystin (50 µM, 3 h), a
specific inhibitor of the proteasome, showed elevated levels of p53, no
positive signals for phosphorylation at serine 15 of p53 were observed (Fig. 3). Similar staining patterns were seen in heat shock-treated (43°C for 45 min, 37°C for 3 h) cells except that less than
2% of cells were positive for the phosphorylation (Fig. 3). These results indicate that phosphorylation at serine 15 is a specific event
after DNA double-strand breakage. To confirm the specificity of the
staining for phosphorylated serine 15 of p53, we carried out two
experiments. First, we tested whether the staining was blocked with the
phosphorylated peptides originally used as antigens to generate the
antibodies. The rabbit antibody was preincubated for 30 min with either
phosphorylated or nonphosphorylated peptides, and normal fibroblasts
microinjected with HaeIII were stained with these antigen-antibody
mixtures. As shown in Fig. 4a,
preincubation with phosphorylated peptides completely blocked the
staining of HaeIII-treated cells, whereas with preincubation with
nonphosphorylated peptides, phosphorylated serine 15 was stained at a
positive control level. Blockage of staining with
phosphorylated antigen peptides was observed with a peptide/antibody
molar ratio of greater than 10. Second, we confirmed the specificity of
the rabbit antibody with Western blotting. Normal fibroblasts used in
this study were irradiated with either X rays or UV. Cell extracts
prepared from the treated cells were electrophoresed, transferred to
membranes, and probed with the serine 15-specific antibody. As shown in
Fig. 4b, p53 was detected in both X- and UV-irradiated cells, and both p53 bands were phosphorylated at serine 15. This phosphorylated band
was the only one which was induced by X irradiation. This finding
excludes the possibility that the observed nuclear staining with the
phosphorylated serine 15 antibody was due to cross-reaction with some
other proteins which were induced following DNA double-strand breaks.
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FIG. 3.
Phosphorylation at serine 15 of p53 following various
types of treatments. Normal fibroblasts (Mori cells) were treated with
X rays (20 Gy, 3 h), heat shock (HS; 43°C for 45 min, 37°C for
3 h), or lactacystin (LC; 50 µM, 3 h). Cells microinjected
with HaeIII (1 U/µl) were cultured for 3 h after injection.
Under these conditions, maximal levels of p53 protein were induced in
normal fibroblasts. Cells were stained for p53 protein with monoclonal
antibody PAb 1801 (top row) or for phosphorylated serine 15 with a
rabbit polyclonal antibody (bottom row).
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FIG. 4.
Specificity of the anti-phosphoserine 15 antibody. (a)
Blocking with phosphorylated peptides. The rabbit antibody against
phosphorylated serine 15 of p53 protein was preincubated for 30 min
with phosphorylated serine peptides (PP), unphosphorylated peptides
(UP), or H2O alone (con) at a peptide/antibody molar ratio
50. Mori cells which had been microinjected with HaeIII (1 U/µl)
and cultured for 3 h were stained with the peptide-antibody
mixtures as shown in Fig. 3. (b) Western blot with the
phosphoserine 15 antibody. Cell extracts prepared from untreated
control (lanes 1 and 5), UV-irradiated (18 J/m2, 5 h)
(lanes 2 and 6), or X-irradiated (20 Gy, 3 h) (lanes 3 and 7) Mori
cells were analyzed with either anti-p53 monoclonal antibody PAb 1801 (lanes 1 to 4) or an anti-phosphoserine 15 rabbit antibody (lanes 5 to
7). Lane 4 is a positive control cell extract prepared from simian
virus 40-transformed human fibroblasts (XP3BRSV). p53 protein bands are
indicated with an arrow.
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To determine the time course of phosphorylation of p53 at serine 15, normal fibroblasts were microinjected with HaeIII, incubated
for
various times, and stained with the antibody. Phosphorylation
occurred
as early as 1 h after microinjection, and high levels
of
phosphorylation continued at least for 6 h (Fig.
5A). This
time course pattern of serine
15 phosphorylation is quite similar
to that of p53 accumulation
(Fig.
2A). When AT cells were treated
with X-rays, small but
significant fractions were positively stained
for phosphorylated serine
15 (Fig.
5C). In contrast, when HaeIII
was microinjected into AT cells,
the frequency of cells showing
phosphorylated serine 15 did not
increase and remained at a basal
level for up to 6 h after
microinjection (Fig.
5B).
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FIG. 5.
Time course of phosphorylation at serine 15 of p53 after
microinjection of HaeIII into normal and AT fibroblasts. HaeIII (1 U/µl) was microinjected into either normal (Mori; A) or AT (AT2KY; B)
fibroblasts. (C) AT fibroblasts treated with X rays (20 Gy). The cells
were cultured for the indicated times and stained for phosphorylated
serine 15. The frequency of phosphoserine 15-positive cells is shown as
the percentage of treated cells showing positive staining. Two
independently performed experiments gave similar results; data from one
experiment are shown.
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Requirement of ATM for phosphorylation of p53 at serine 15.
Neither p53 accumulation nor phosphorylation at serine 15 of p53 was
observed in AT cells following microinjection of HaeIII (Fig. 2B and
5B). To determine whether p53 accumulation was required for
phosphorylation at serine 15 or vice versa, we microinjected HaeIII
into normal or AT cells where high levels of p53 protein had been
induced by treatment with lactacystin for 3 h. As shown in Fig.
6 and 7,
p53 protein levels were enhanced to similar levels in normal and AT
cells as determined by Western blotting and immunostaining, respectively. But in both cell types, phosphorylation at serine 15 was
not observed in the accumulated p53 as determined by double staining
(Fig. 7). High levels of p53 protein were maintained even when these
cells were cultured for another 3 h in the presence of
cycloheximide (Fig. 6). When HaeIII was microinjected into lactacystin-treated normal cells, the up-regulated p53 protein was
phosphorylated at serine 15 within 3 h in the presence of cycloheximide. In these cells, enhanced levels of p53 protein phosphorylated at serine 15 were sustained for at least 12 h even in the presence of cycloheximide, while levels of p53 protein without
the phosphorylation in nonmicroinjected cells returned nearly to the
basal level (data not shown). In contrast, even when HaeIII was
microinjected into lactacystin-treated AT cells, no phosphorylation at
serine 15 was observed (Fig. 7). These results indicate the requirement
of ATM for the phosphorylation at serine 15, which results in
stabilization of p53.
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FIG. 6.
Accumulation of p53 protein in normal (Mori) and AT
(AT2KY) fibroblasts induced by treatment with a proteasome inhibitor.
Normal (lane 2) and AT (lane 5) fibroblasts were treated with
lactacystin (50 µM) for 3 h. Some cells were treated with
lactacystin (50 µM) for another 3 h in the presence of
cycloheximide (20 µM) (lanes 3 and 6). p53 protein levels were
determined by Western blotting with anti-p53 monoclonal antibody PAb
1801. Lanes 1 and 4 are extracts prepared from untreated cells.
p53 bands are indicated with an arrow.
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FIG. 7.
Phosphorylation at serine 15 of lactacystin-induced p53
protein following DNA double-strand breaks. Normal (Mori) and AT
(AT2KY) fibroblasts were cultured for 3 h in the presence of
lactacystin (50 µM) (LC), HaeIII (1 U/µl) was microinjected, and
the cells were cultured for another 3 h in the presence of
cycloheximide (20 µM) and lactacystin (50 µM) (LC + HaeIII).
Fixed cells were double stained for p53 (top row) and phosphorylated
serine 15 (bottom row); the same fields are shown. Perinuclear
fluorescence was nonspecific staining due to the double staining.
Arrows indicate microinjected cells containing p53 phosphorylated at
serine 15. Note that lactacystin-induced p53 was phosphorylated at
serine 15 following DNA double-strand breaks in normal cells, whereas
p53 protein accumulated in AT cells was not phosphorylated after the
same treatment.
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No phosphorylation is observed at serine 37 of p53 after DNA
damage.
Phosphorylation of serine 37 is also thought to contribute
to p53 stabilization (28). We used a phosphorylated serine
37-specific antibody to determine whether phosphorylation occurred at
this site on p53 in normal or AT cells after various cellular stresses. Although this antibody reacted specifically with the phosphorylated peptide antigen immobilized on a slide glass, we could not detect any
positive staining in normal or AT cells treated with HaeIII, X rays, or
UV. Furthermore, even when normal cells containing high levels of p53
protein induced by treatment with lactacystin were X irradiated or
microinjected with HaeIII, no positive staining was observed
(data not shown).
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DISCUSSION |
Using two novel experimental approaches, we have demonstrated that
DNA double-strand breaks lead to the ATM-dependent phosphorylation of p53 protein at serine 15. First, instead of IR, we microinjected restriction endonucleases into cells to introduce DNA double-strand breaks. Unlike high-energy irradiation, which causes various types of
cell damage due to activated oxygen radicals, the only known action of
restriction endonucleases is to cut DNA at specific nucleotide
sequences. Second, instead of Western blotting, phosphorylation of p53
protein was detected by immunostaining with phosphoserine-specific antibodies. The staining in this study was judged to be specific for
phosphorylated p53 for the following reasons: (i) positive staining was
blocked with phosphorylated peptides corresponding to the p53
phosphoserine epitope; (ii) no inducible protein bands other than p53
were detected after X irradiation using Western blotting, and (iii)
positive staining was observed after the introduction of DNA
double-strand breaks in normal and XP cells but not in AT cells.
Generally, staining methods have advantages over biochemical methods in
morphological studies. Using double staining for p53 protein and
phosphorylated serines of p53 protein, we can determine whether
accumulated p53 protein is phosphorylated at specific sites in a single
cell. Thus, it was revealed that only p53 protein phosphorylated at
serine 15, as a result of HaeIII treatment, was stabilized even after
long culture periods in the presence of cycloheximide (Fig. 7). It is
reported that p53 accumulation (4, 15), and phosphorylation
(29) after IR in AT cells is reduced and/or delayed compared
with that in normal cells (14). We confirmed these earlier
observations in the present study using our AT cells and methods (Fig.
2C and 5C). We did not, however, observe such a delayed type
of p53 accumulation in AT cells after microinjection of HaeIII. The
complete absence of a p53 response in HaeIII-treated AT
cells strongly suggests that the observed p53 accumulation after IR
treatment may be caused by some unknown effects other than DNA
double-strand breaks.
Phosphorylation at serine 15 was absolutely required for stabilization
of p53 protein after DNA double-strand breaks. However, the results in
the present study do not exclude the possibility that additional
phosphorylation of p53 protein or its association with some other
protein(s) is required for the stabilization. In this regard, it was of
interest to determine whether serine 37 was also phosphorylated
after DNA double-strand breaks, because this serine is phosphorylated
by DNA-PK in vitro (19). However, we did not detect
phosphorylation at this site after various kinds of DNA damage in our
assay system. Given that nonphysiological phosphorylation is
often seen in vitro, it is likely that this site may not be
phosphorylated in an intact cell after DNA double-strand breaks.
Alternatively, though serine 37 is phosphorylated, our antibody may
not react with the phosphorylated serine due to steric hindrance
caused by phosphorylation at serine 15. Such a situation is
known to occur at the C-terminal domain of p53. When serine 376 is
phosphorylated, an antibody against phosphorylated serine 378 cannot
bind to the phosphorylated serine (31).
We could not detect phosphorylation at serine 15 in AT cells following
DNA double-strand breaks. Furthermore, because cells from
scid mice, which are defective in DNA-PK, show a normal
IR-induced p53 response (26), DNA-PK does not appear to be
involved in the phosphorylation of this site following DNA
double-strand breaks. Nijmegen breakage syndrome is another
radiosensitive disorder whose cells manifest similar characteristics to
those of AT cells, including an abnormal IR-induced p53 response
(13). Nijmegen breakage syndrome protein, named nibrin,
complexes with Mre11 and Rad50. The Mre11-Rad50 protein complex can
bind to the ends of severed DNA strands (5). Mec1, the
Saccharomyces cerevisiae homologue of ATM, interacts with a
protein complex including Ddc1 and Mec3 (24). It is tempting
to speculate that the nibrin complex acts as a sensor of DNA
double-strand breaks, with the signal being transduced directly or
indirectly to the Ddc1 complex, so that ATM protein is activated to
some phosphorylate specific site(s) of p53 protein for its
stabilization and activation as a transactivator. Phosphorylation
at serine 15 took place even in the presence of cycloheximide (Fig.
7), suggesting that the signal arising from double-strand
breakage does not require newly synthesized protein(s). As reported by
Siliciano et al. (29), following UV irradiation, phosphorylation at serine 15 was observed in not only normal
fibroblasts (Fig. 4b) but also AT fibroblasts (data not shown). These
results indicate that there is an ATM-independent signaling pathway for the phosphorylation at serine 15. Furthermore, since phosphorylation at
serine 15 was observed in only a minor fraction of normal cells treated
with heat shock (Fig. 3), the signaling pathway evoked by heat shock is
different from that which is activated by DNA double-strand breaks.
During the preparation of this report, Canman et al. (3) and
Banin et al. (1) demonstrated independently that ATM is activated following IR and directly involved in the phosphorylation of
p53 protein at serine 15. Our present data are consistent with their results.
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ACKNOWLEDGMENTS |
We are grateful to Michael Kastan and Carol Prives for helpful discussions.
This work was supported by a Grant-in-Aid for Scientific Research on
Priority Areas from the Ministry of Education, Science, Sports, and
Culture of Japan (08280101). Y.T. is supported by a grant from the
Ministry of Health and Welfare of Japan for the second-term
comprehensive 10-year strategy for cancer control.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular Embryology and Genetics, Kumamoto University School of
Medicine, Kuhonji 4-24-1, Kumamoto 862-0976, Japan. Phone:
81(96)373-5340. Fax: 81(96)364-3554. E-mail:
yamaizm{at}gpo.kumamoto-u.ac.jp.
| |
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Molecular and Cellular Biology, April 1999, p. 2828-2834, Vol. 19, No. 4
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
