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Previous Article | Next Article 
Molecular and Cellular Biology, March 2001, p. 1719-1729, Vol. 21, No. 5
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.5.1719-1729.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Phosphorylation and Rapid Relocalization of 53BP1
to Nuclear Foci upon DNA Damage
Lindsay
Anderson,
Catherine
Henderson, and
Yasuhisa
Adachi*
The Wellcome Trust Centre for Cell Biology,
Institute of Cell & Molecular Biology, University of Edinburgh,
Edinburgh EH9 3JR, United Kingdom
Received 29 August 2000/Returned for modification 12 October
2000/Accepted 6 December 2000
 |
ABSTRACT |
53BP1 is a human BRCT protein that was originally identified as a
p53-interacting protein by the Saccharomyces cerevisiae two-hybrid screen. Although the carboxyl-terminal BRCT domain shows
similarity to Crb2, a DNA damage checkpoint protein in fission yeast,
there is no evidence so far that implicates 53BP1 in the checkpoint. We
have identified a Xenopus homologue of 53BP1 (XL53BP1). XL53BP1 is associated with chromatin and, in some cells, localized to a
few large foci under normal conditions. Gamma-ray irradiation induces
increased numbers of the nuclear foci in a dose-dependent manner. The
damage-induced 53BP1 foci appear rapidly (in 30 min) after irradiation,
and de novo protein synthesis is not required for this response. In
human cells, 53BP1 foci colocalize with Mrel1 foci at later stages of
the postirradiation period. XL53BP1 is hyperphosphorylated after X-ray
irradiation, and inhibitors of ATM-related kinases delay the
relocalization and reduce the phosphorylation of XL53BP1 in response to
X-irradiation. In AT cells, which lack ATM kinase, the
irradiation-induced responses of 53BP1 are similarly affected. These
results suggest a role for 53BP1 in the DNA damage response and/or
checkpoint control which may involve signaling of damage to p53.
| |
INTRODUCTION |
Double-stranded DNA (dsDNA) breaks
are potentially dangerous to cells since they may lead to chromosome
breakage and loss of genetic information. However, transient dsDNA
breaks are essential to initiate recombination or to solve topological
problems at the end of DNA synthesis (24, 58, 63). dsDNA
breaks can also occur if replication forks are stalled (e.g., due to
base modifications, single-stranded-DNA gaps, or low deoxynucleoside triphosphate pools), and in Escherichia coli, RuvABC
Holliday junction resolvase has been shown to catalyze the breakage
(53, 68). In general, cells do not enter S or M phase
before the DNA lesions are properly repaired due to the action of the
DNA damage checkpoint (19). The sensitivity of cancer
cells to DNA-damaging agents is explained by the fact that cancer cells
have often lost some aspects of checkpoint function, which has provided
them with a higher rate of genomic evolution to acquire a growth
advantage (18).
The DNA damage checkpoint is a signal transduction cascade that relays
information from DNA lesions to components of the cell cycle (reviewed
in references 5, 40, and 41). In response to DNA damage,
ATM-related protein kinases (ATM, ATR, and possibly DNA-PK) activate
the downstream effector checkpoint kinases Chk1 and Chk2 (28, 35,
62). Then Chk2 (homologues are Rad53 in budding yeast and Cds1
in fission yeast) phosphorylates p53 or Cdc25A, which arrests the cell
cycle at the G1/S or G2/M boundary, respectively (6, 7, 8, 20, 54). Compared to these downstream events, the molecular mechanism of how DNA lesions activate
the kinase cascade is not well understood. Yeast genetics have
identified candidate genes that appear to be involved in these early
sensing and processing stages. These genes are classified into three
groups: yeast homologues of ATM-related kinases that are structurally
similar to phosphatidylinositol 3 kinase
(Rad3sp/Mec1sc and Tel1; superscripts are sp
for fission yeast and sc for budding yeast genes, respectively),
putative sliding clamp and clamp loader complexes structurally related
to PCNA and RFC (e.g., Rad1sp, Hus1sp, and
Rad17sp), and proteins with BRCT domains
(Crb2sp/Rad9sc). In response to DNA damage,
ATM-related kinases are activated by unknown mechanisms and the
putative sliding clamp components are phosphorylated (13, 27,
42). The sliding clamp and its loader are required for the
phosphorylation of BRCT proteins, and BRCT proteins are required for
phosphorylation and activation of the checkpoint kinases
(48). The carboxyl (C) termini of BRCT proteins contain a
tandem repeat of BRCT domains, each consisting of ~95 amino acid
residues, that was first identified in BRCA1 (3). In human
and in mouse, BRCA1 is thought to function as a counterpart of the BRCT
proteins in yeasts. A number of observations indicate that the BRCT
domain promotes protein-protein interactions (11, 34, 37).
In contrast to their C termini, the amino (N) termini of BRCT proteins
are not homologous to each other and the molecular functions of these
large N-terminal domains are totally unknown.
Some proteins involved in repair or checkpoint control are relocalized
to nuclear foci after DNA damage. These include BRCA1, Rad51, and the
Mre11-Rad50-Nbs1 complex (33, 43, 52, 64). Although the
functional significance of these damage-induced foci is unknown, the
increased local concentration of the proteins facilitates their
functions, such as enzymatic and signal transduction processes.
53BP1 is a human BRCT protein that was originally identified by the
yeast two-hybrid screen using p53 as a bait (22). The protein consists of 1,972 amino acid residues and has a tandem repeat
of the BRCT domain at its C terminus, which shows similarity to the
BRCT domain of Crb2sp (48). Although 53BP1 was
shown to stimulate p53-mediated transcription in a
transient-transfection assay (23), so far there is no
evidence implicating this protein in the DNA damage checkpoint and/or
repair pathway. To investigate this possibility, we have cloned a
Xenopus homologue of 53BP1 and raised antibodies against the
protein. As an initial step towards the understanding of the function
of 53BP1, we examined the behavior of XL53BP1 in frog cell lines in
response to DNA damage. We found that 53BP1 is relocalized to a number
of nuclear foci after DNA damage. dsDNA breaks are most effective in
inducing this focal phenotype. The focal redistribution of 53BP1
appears to be related to the extent of its phosphorylation, which is
also induced by DNA damage. We will discuss a functional involvement of
ATM-related kinases in the focal relocalization of 53BP1.
| |
MATERIALS AND METHODS |
Cell culture and drug treatments.
A Xenopus cell
line (XTC-2) was grown in a solution containing 60% Leibovitz L-15,
10% fetal calf serum, and 5 to 50 µg of gentamicin per ml at room
temperature (55). Human cells (HT1080 and the AT cell line
AT1BR/11 obtained from the MRC Cell Mutation Unit, University of
Sussex) were grown in Dulbecco's modified Eagle's medium, 10% fetal
calf serum, and 5 µg of gentamicin per ml at 37°C with 5%
CO2. For treatment with caffeine (0.5 M stock solution in
H2O) or with wortmannin (10-mg/ml stock solution in dimethyl sulfoxide [DMSO]; Sigma), XTC-2 cells grown on cover slips
were preincubated for 1 h in media containing either 16 mM caffeine or
23 µg of wortmannin per ml before the X-ray irradiation. Cycloheximide (50-mg/ml stock solution in ethanol) and actinomycin D
were used as described above at 50 and 25 µg/ml, respectively.
Cloning of XL53BP1 and plasmid construction.
Xenopus cDNA encoding a 53BP1 homologue was cloned by
low-stringency hybridization. A Xenopus oocyte cDNA library
in lambda gt10 (45) was screened with human cDNA encoding
from Ser 1618 to Pro 1963 of human 53BP1 (23).
Hybridization was performed at 30°C in a solution of 5× SSPE (1×
SSPE is 0.18 M NaCl, 10 mM NaH2PO4, and 1 mM EDTA [pH 7.7]), 50% formamide, 5× Denhardt's solution, 0.5%
sodium dodecyl sulfate (SDS) and 8% dextran sulfate for 16 h. The
filters (Hybond-N+; Amersham Pharmacia Biotech) were washed twice at
room temperature with 2× SSPE-0.1% SDS and twice at 58°C with 1×
SSPE-0.1% SDS. The length of the combined sequences of several
overlapping clones was 5,387 bp, and the longest open reading frame
(ORF) was 1 to 5199 bp, encoding 1,733 C-terminal amino acid residues.
Antibody preparation.
The 1.5-kb
HindIII-EcoRI fragment of XL53BP1 cDNA was
cloned into the pRSET plasmid (Invitrogen), and the recombinant
protein, tagged with six histidines, was expressed in BL21 (DE3) with
pLysS. The protein found in an insoluble fraction was run on an
SDS-polyacrylamide gel, eluted by diffusion, and used as an antigen to
immunize rabbits (1). Poly(A) · poly(U) was used as
an adjuvant (21). The corresponding domain of human 53BP1
was expressed and used for the antigen as described above. Antibodies
were affinity purified with an antigen column as follows. The insoluble
fraction containing approximately 10 mg of the His-tagged recombinant
protein was solubilized with 6 M guanidine-HCl and loaded onto 1 ml of
Ni-nitrilotriacetic acid agarose (Qiagen). The protein was renatured on
the column by applying a 6 to 1 M urea gradient essentially according
to the manufacturer's instructions. The peak fractions were pooled and
dialyzed against HNG buffer (0.5 M NaCl, 10% glycerol, 10 mM
HEPES-NaOH [pH 7.5]) overnight at 4°C. The dialyzed fractions containing the solubilized recombinant proteins were coupled to Affigel
10 (Bio-Rad) by following the instructions supplied by the
manufacturer. Approximately 1 mg of the recombinant protein was coupled
to 1 ml of the Affigel resin. Affinity column chromatography was
performed essentially according to a standard procedure
(17). The antibodies were concentrated to ~1 ml with
Centricon 30 (Amicon), dialyzed against an appropriate buffer, and
stored at 
80°C in aliquots.
Immunoprecipitation and immunoblotting.
XTC-2 or HT1080
cells were rinsed briefly with Marc's modified ringer's solution
(MMR; 100 mM NaCl, 2 mM KCl, 2 mM CaCl2, 1 mM
MgCl2, 5 mM HEPES-NaOH [pH 7.4] [55]) or
with phosphate-buffered saline (PBS), respectively. The dishes were
placed on ice and LA buffer (50 mM HEPES-NaOH [pH 7.5], 0.5 mM EDTA,
80 mM 
-glycerophosphate, 1 mM Na-vanadate, 10% glycerol, 1 mM
phenylmethylsulfonyl fluoride [PMSF], 1 mM dithiothreitol [DTT], 1 µM lactacystin, 1% NP-40, 50 mM NaF, 400 mM NaCl, 1× protein
inhibitor cocktail) was applied at 6.7 µl/cm2. Protein
inhibitor cocktail (1,000×) contained 10 mg each of leupeptin,
pepstatin A, chymostatin, and antipain per ml in DMSO. Cells were
scraped off with a silicon rubber scraper, and the cell lysates were
spun for 10 min in a microcentrifuge at 4°C. The supernatants were
stored at 80°C. Protein concentrations were estimated by the
Bradford assay (4) using bovine serum albumin (BSA) as a
standard. Immunoprecipitation was performed as follows. Four hundred
fifty microliters of the cell lysates was diluted with 900 µl of
dilution buffer (10 mM HEPES-NaOH [pH 7.5], 0.5 mM EDTA, 10 mM
-glycerophosphate, 1 mM Na-vanadate, 0.1 mM PMSF, 0.5 mM DTT, 0.02%
NP-40) and spun for 10 min in a microcentrifuge at 4°C. The
supernatants were added with 6 µg of the affinity-purified antibodies
and incubated for 1 h at 4°C on a rotating wheel. Twenty
microliters of proteins A-agarose beads (Gibco BRL) was added, and
incubation was continued for 1 h. The beads were washed five times
with washing buffer (10 mM HEPES-NaOH [pH 7.5], 0.5 mM EDTA, 10 mM
-glycerophosphate, 50 mM NaF, 100 mM NaCl, 1 mM Na-vanadate, 0.1 mM
PMSF, 0.5 mM DTT, 0.02% NP-40). The proteins were eluted with 20 to 50 µl of denaturation buffers appropriate for the following gel
electrophoresis. For phosphatase treatments of immunoprecipitates, the
resins were washed three times with Tris-buffered saline, resuspended
in 15 µl of phosphatase buffer (50 mM Tris-HCl [pH 7.5], 0.1 mM
EDTA, 5 mM DTT, 0.01% Brij 35, and 2 mM MnCl2) plus 400 U
of lambda protein phosphatase (New England Biolabs), and incubated for
30 min at 30°C. The reaction was stopped by adding EDTA to 5 mM and appropriate sample buffers for gel electrophoresis. Proteins were separated on standard Laemmli gels (5 to 12% gradient
[29]) or on NuPAGE Tris-acetate gels (3 to 8% gradient;
Novex). For Laemmli gels, the proteins were electrotransferred onto
nitrocellulose filters with Tris-glycine buffer containing 10%
methanol (60). For NuPAGE gels, we followed the protocol
supplied by the manufacturer. The filters were blocked with 5% skimmed
milk in Tris-buffered saline and probed with 1 µg of the
affinity-purified antibodies per ml. Preimmune sera were diluted to
1:1,000 and used for blotting. The antibodies conjugated with
peroxidase were used as secondary antibodies. Enhanced
chemiluminescence was used for detection.
Immunofluorescence staining.
Essentially the standard
procedure was followed (17). XTC-2 cells grown on
coverslips were briefly rinsed with MMR and fixed with freshly prepared
3% paraformaldehyde in MMR for 10 min. The cells were permeabilized in
0.5% Triton X-100 in PBS for 2 min at room temperature. After being
washed with PBS, the coverslips were blocked in 3% BSA in PBS for
1 h. HT1080 cells were fixed and permeabilized in 50%
methanol-50% acetone at 20°C for 2 min. The first antibodies were
affinity-purified antibodies diluted to 10 µg/ml in 3% BSA in PBS.
Preimmune serum was used at a 1:100 dilution as a negative control.
Antibodies were labeled with fluorescein isothiocyanate (FITC) as
described previously (17). For double labeling of HT1080
cells, cells were first probed with anti-Mre11 antibodies (Novus
Biologicals) that are detected by the anti-rabbit immunoglobulin G Cy5.
Then the samples were fixed with paraformaldehyde, followed by blocking
and probing with anti-53BP1 antibody-FITC. The coverslips were mounted
in 85% glycerol-2.5% propyl gallate-2.5 µg of DAPI
(4',6'-diamidino-2-phenylindole) per ml. Double labeling with
anti-53BP1 antibody and bromodeoxyuridine was performed as follows.
XTC-2 cells on cover glasses were incubated in the presence of 10 µg
of bromodeoxyuridine per ml for 2 h, fixed, and stained with
anti-XL53BP1 antibody as described above using secondary antibodies
conjugated with rhodamine. After the final wash, the cells were fixed
again, rinsed with PBS twice, and treated with 50,000 U of DNase I per
ml in a solution containing 150 mM NaCl, 10 mM sodium acetate (pH 5.2),
10 mM MgCl2, and 100 µg of BSA per ml for 30 min at room
temperature. The cover glasses were rinsed three times with PBS and
probed with monoclonal antibodies against bromodeoxyuridine (Roche
Molecular Biology), which was then detected by FITC-labeled secondary
antibodies. Images were recorded with either a conventional microscope
(Zeiss Axioskop microscope equipped with a VYSIS image recording
system) or a confocal microscope (Leica).
Nucelotide sequence accession number.
The sequence data for
XL53BP1 are available from the DDBJ, EMBL, and GenBank databases under
accession no. AJ298224 and XLA298224.
| |
RESULTS |
Isolation of a Xenopus 53BP1 homologue, XL53BP1.
We cloned a cDNA encoding a Xenopus 53BP1 homologue by
low-stringency hybridization. The human cDNA sequence encoding the C-terminal 345 amino acid residues was amplified by PCR and used as a
probe to screen a Xenopus oocyte cDNA library. The longest clone obtained in the first screening encoded only 60% of the expected
full length, and another screening was performed using the 5' end of
the first-round clone as a probe. The combined sequence of the
overlapping clones had an open reading frame of 1,737 amino acid
residues but still lacked the N terminus (N.B., human 53BP1 is 1,972 amino acids long). The carboxyl-terminal 1,100 amino acid residues of
XL53BP1 shares 57% identity and 80% similarity with human 53BP1. The
N-terminal half of XL53BP1 shows low similarity to the human protein
(data not shown). One common feature of the N-terminal halves of human
and Xenopus 53BP1 is the presence of SQ/TQ motifs spread
throughout the region (22 motifs for the human and 9 for the
Xenopus 53BP1). SQ/TQ motifs are the preferred
phosphorylation sites of members of the ATM-related kinase family
(25). In addition, both proteins are rich in acidic amino
acid residues (with a pI of 4.0 for the human and a pI of 4.3 for the
Xenopus 53BP1).
53BP1 exists as an oligomeric protein complex.
We raised
antibodies against the C-terminal 500 amino acid residues of XL53BP1
and those of human 53BP1, both of which were produced in E. coli. Affinity-purified anti-XL53BP1 and anti-HS53BP1 antibodies
recognized a single protein of ~300 kDa by immunoblotting (Fig.
1A, lanes 1 and 4). Preimmune sera showed
only very weak reactions with proteins in the extracts (lanes 2 and 3;
note that, after the affinity purification, those minor bands
disappeared). Thus, in SDS-polyacrylamide gel electrophoresis
Xenopus and human 53BP1 appeared to migrate significantly
more slowly than expected from the primary sequence. Slower migration
of 53BP1 was previously reported for human 53BP1, in which its identity
was confirmed by hemagglutinin epitope tagging (23).
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FIG. 1.
(A) Verification of antibodies against 53BP1 and
immunoprecipitation. Cell lysates were prepared from Xenopus
cells (XTC-2), (lanes 1 and 2) or from HeLa cells (lanes 3 and 4), run
on an SDS-polyacrylamide gel, and subjected to immunoblotting.
Affinity-purified anti-XL53BP1 (Xenopus cells; lane 1) or
anti-HS53BP1 (human; lane 4) antibodies react with single proteins in
the extracts. Preimmune sera were used as negative controls (lanes 2 and 3). Lane 6, fluorography of immunoprecipitate (IP) with
anti-HS53BP1 antibody from 35S-labeled HeLa cell extracts
lane 5, immunoprecipitation with preimmune serum control. (B) Gel
filtration of HeLa cell extracts. The extract (Lo) was loaded on a
Superdex 200 (10/30) column, and the fractions were analyzed by
immunoblotting with anti-HS53BP1 antibodies. Positions where the
molecular mass markers were eluted are indicated below the gel in
kilodaltons.
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Anti-HS53BP1 antibodies precipitated the protein with an apparent
molecular mass of 300 kDa from HeLa cell extracts labeled with
[35S]methionine-cysteine (Fig. 1, lane 6). There also
appeared to be several other proteins that coimmunoprecipitated with
53BP1. The preimmune serum control precipitated no detectable proteins (lane 5). Separation of the HeLa cell extracts by a gel filtration column (Superdex 200) showed that 53BP1 was eluted in fractions larger
than 669 kDa (approximately 1 MDa) (Fig. 1B). These results suggested
that 53BP1 existed as an oligomeric protein complex.
XL53BP1 is associated with nuclear foci that are induced by various
DNA-damaging agents.
Some of the proteins involved in the DNA
damage repair checkpoint are known to change their localization in
response to DNA damage. To determine whether this is the case for
53BP1, we examined the cellular localizations of XL53BP1 under
differing conditions. The Xenopus cell line XTC2 was fixed
and stained with affinity-purified anti-XL53BP1 antibodies. XL53BP1
showed an exclusively nuclear localization in interphase cells (Fig.
2A). Cells stained with preimmune serum
showed little signal under the experimental conditions (Fig. 1B; images
were recorded under the same sensitivity setting for panels A to E). In
mitosis, XL53BP1 appeared to be dissociated from mitotic chromosomes
and was dispersed throughout the cytoplasm (data not shown; see Fig. 5
for human cells). The nuclear XL53BP1 appeared to exist as two
populations. One was distributed homogeneously over the chromatin, and
the other was associated with a few large foci inside the nucleus.
Since the preimmune serum control did not show any chromatin signal,
the overall chromatin staining was due to XL53BP1 and not nonspecific
background. Often the bright foci were adjacent to nucleoli (Fig. 2A;
the nucleolus appears as a dark hole with the XL53BP1 stain). On
average, one nucleus had 2.1 ± 3.4 XL53BP1 foci. Approximately
half of the nuclei did not have any XL53BP1 foci. Double labeling with
anti-XL53BP1 antibody and with bromodeoxyuridine for S-phase nuclei
indicated that there was no obvious relationship between the presence
of bright XL53BP1 foci and S phase (data not shown).
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FIG. 2.
XL53BP1 localizes to nuclear foci, which increase in
number after DNA damage. Xenopus XTC-2 cells were
immunostained with anti-XL53BP1 antibodies. (A) In control cells, there
were two types of XL53BP1 populations. One was homogeneously
distributed over chromatin, and the other was associated with large
foci. (B) Staining with preimmune serum showed very little background.
(C to E) After exposure to  rays, XL53BP1 formed increased numbers
of smaller foci dispersed throughout the nucleus. -Ray dosages were
1.5 Gy (C), 7.5 Gy (D), and 20 Gy (E). (F to I) XL53BP1 foci were also
induced by various DNA-damaging agents. Cells were subjected to 3.3 µg of VM26 per ml (F), 60 µg of mitomycin C per ml (G), 300 J
of UV per m2 (H), and 10 mM hydroxyurea (HU) (I). Cells
were fixed for staining at 2 h postirradiation or at 16 h
after addition of the chemicals.
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We next investigated the effects of ionizing irradiation on the
localization of XL53BP1. XTC-2 cells were exposed to increasing doses
of rays, fixed after 2 h of incubation, and stained for XL53BP1 (Fig. 2C to E). Exposure to rays caused the appearance of
an increased number of smaller XL53BP1 foci inside the nuclei in most
of the cells. We performed optical sectioning using a confocal
microscope and scored the number of XL53BP1 foci per nucleus for 100 cells. The number of XL53BP1 foci increased in a dose-dependent manner
(Fig. 3A).
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FIG. 3.
(A) -Ray-dose-dependent increase of XL53BP1 focal
number. The average number of foci per nucleus was plotted versus
radiation dose. Error bars indicate standard deviations. (B) Recovery
of the XL53BP1 focal phenotype after -ray irradiation. XTC-2 cells
were either untreated (stippled bars) or irradiated with 5 Gy of rays (black bars) and fixed for XL53BP1 staining at 2 h or at 24 h
postirradiation. Optical sections were recorded by confocal microscope.
The number of XL53BP1 foci per nucleus was counted in 150 cells for
each sample. At 2 h postirradiation, the nuclei had 10.9 ± 3.2 XL53BP1 foci (upper graph, black bars). At 24 h
postirradiation, the average focus number per nucleus decreased to
1.99 ± 2.15 (lower graph, black bars), which was equivalent to
that of the untreated control cells (stippled bars).
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We examined the localization of XL53BP1 in cells treated with other
DNA-damaging agents (Fig. 2F to I). The results of the treatments
examined were as follows: VM26 inhibited topoisomerase II activity by
stabilizing the covalent dsDNA break protein intermediate (Fig. 2F)
(9), mitomycin C cross-linked interstrand DNA (Fig. 2G),
UV induced pyrimidine dimer formation (Fig. 2H) and hydroxyurea reduced
the cellular deoxynucleoside triphosphate concentration through
inhibiting ribonucleotide reductase (Fig. 2I). It is worth noting that
each agent may generate various other lesions as secondary or tertiary
effects. We observed that ionizing irradiation (X or rays) and VM26
treatments were most effective at inducing the formation of numerous
smaller XL53BP1 foci (Fig. 2C to F; see also Fig. 5). The other
treatments were less effective and induced smaller and fewer 53BP1 foci
(Fig. 2G to I).
The XL53BP1 foci dissociate upon recovery from DNA damage.
In
order to determine the fate of the XL53BP1 foci after the lesions were
repaired, we examined the XL53BP1 localization 24 h postirradiation
(26, 39). XTC-2 cells were exposed to 5 Gy of rays. In
separate experiments, more than 95% of the cells survived at this dose
of irradiation (data not shown). We noted that XTC-2 cells were
significantly more resistant to -ray irradiation than mouse or human
cells for unknown reasons. (Only 20% of mouse cells survived under the
same conditions. This might be partly due to the fact that the
Xenopus genome has ancient tetraploid features.) The cells
were fixed at 2 h or at 24 h postirradiation and stained for
XL53BP1. The number of foci per nucleus was counted in 150 cells and
scored (Fig. 3B, black bars). Nonirradiated cells served as a control
(stippled bars). At 2 h postirradiation, the average number of
XL53BP1 foci per nucleus increased to 10.9 ± 3.2 from 0.73 ± 0.98 in the nonirradiated control (Fig. 3B, upper graph). At 24 h
postirradiation, the number decreased to 1.99 ± 2.15 foci per
nucleus. This number was indistinguishable from the value (2.13 ± 1.95) for the nonirradiated control at the same time point (lower
graph). These results indicated that the XL53BP1 foci assembled
transiently in response to DNA damage and that they dissociated at
later times, presumably after the lesions were repaired.
XL53BP1 is relocalized to the damage-induced foci: de novo
synthesis is not required.
Is the induction of XL53BP1 foci in
response to DNA damage due to an increased level of protein expression?
To answer this question, we examined whether the inhibition of
transcription or translation would block the assembly of XL53BP1 foci.
XTC2 cells were exposed to 5 Gy of rays in the presence of either cycloheximide or actinomycin D, and after 2 h of incubation the cells were stained for XL53BP1. As shown in Fig.
4, the damage-induced XL53BP1 foci
assembly occurred efficiently in the presence of these inhibitors
(compare Fig. 4B to D). There were slight increases in the numbers of
XL53BP1 foci per nucleus after irradiation in the presence of these
inhibitors, although the reason for this was unknown. In a control
experiment, there was very little incorporation of35S-labeled amino acids into proteins in the presence of
50 µg of cycloheximide per ml (data not shown). To further confirm
these results, we compared the amounts of XL53BP1 in cells exposed or not exposed to rays by quantitative immunoblotting (Fig. 4E). We
did not observe any change of the XL53BP1 levels before and after
exposure to rays (compare lanes 1, 2, and 3). These results indicated that the increased number of XL53BP1 foci in cells after ionizing irradiation was due to relocalization of the protein that was
already there and that de novo synthesis was not required.
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FIG. 4.
Neither inhibitors of transcription nor translation
blocks the assembly of XL53BP1. XTC-2 cells were irradiated with 5 Gy
of rays in the presence of 50 µg of cycloheximide (Cyh) per ml
(C) or 25 µg of actinomycin D (Act) per ml (D). (A) Nonirradiated
control. (B) Cells irradiated without the inhibitors. (E) the amount of
XL53BP1 did not increase after -ray irradiation. XTC-2 cells were
exposed to 5 or 15 Gy of rays, and at 2 h after irradiation,
cell extracts were prepared for immunoblotting with anti-XL53BP1
antibody. Each slot was loaded with the same amount of proteins.
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Colocalization of 53BP1 foci with Mre11 foci in human cells.
As described above, XL53BP1 relocalized to nuclear foci transiently in
response to DNA damage. In the absence of DNA damage, the protein did
not appear to change its localization in a cell cycle-dependent manner
except in M phase. This behavior of XL53BP1 is quite similar to that of
the Rad50-Mre11-Nbs1 complex in human cells (33, 38). To
investigate the spatial relationship between 53BP1 and Mre11, we
monitored the kinetics of 53BP1 and Mre11 focus assembly in response to
DNA damage in the human fibrosarcoma cell line HT1080. HT1080 cells
were either untreated or exposed to 84 Gy of X rays, fixed at 15 h
postirradiation and doubly stained with anti-53BP1 (detected by FITC)
and anti-Mre11 (detected by Cy5) antibodies (Fig. 5A to
F). Increased numbers of smaller 53BP1 foci were induced in response to X-ray irradiation (Fig. 5B). At this
later time postirradiation, in 40% of cells, Mre11 localized to
discrete foci as previously reported (Fig. 5D) (33). Mre11 foci showed almost 100% colocalization with 53BP1 foci in these cells
(Fig. 5F, a merged image of panels B and D). In untreated HT1080 cells,
there were smaller numbers of 53BP1 foci and the cells had Mre11 foci
at the corresponding sites, although the Mre11 signals were not as
prominent as 53BP1 signals (Fig. 5A, C, and E). It is worth noting that
bleedthrough of the FITC and Cy5 signals to the opposite channel was
minimal under the experimental conditions (data not shown).
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FIG. 5.
Colocalization of 53BP1 foci and Mre11 foci in
human HT1080 cells. HT1080 cells untreated (A, C, and E) or exposed to
84 Gy of X rays (X) (B, D, and F) were fixed at 15 h
postirradiation and double stained with Cy5 for Mre11 (C and D;
pseudo-colored in red) and with FITC for 53BP1 (A and B; green). (E and
F) Merged images of panels A and C and of B and D, respectively.
Colocalization of green foci and red foci yields yellow signals. The
cell marked by an arrowhead in panels B and D had 53BP1 foci but not
discrete Mre11 foci. The cells marked by asterisks in panels C and D
were in mitosis, and 53BP1 and Mre11 were dissociated from mitotic
chromosomes and spread throughout the cytoplasm. (G) Kinetics of 53BP1
and Mre11 focal formation. HT1080 cells were either untreated (0 h) or
irradiated with X rays, fixed at the indicated times postirradiation,
and stained independently for either 53BP1 or Mre11. Optical sections
were recorded by confocal microscope. The number of 53BP1 foci (upper
graph) or Mre11 (lower graph) foci per nucleus was counted in 50 cells
for each sample. Nuclei were categorized as having 0 to 5 foci (blue
bars), 6 to 30 foci (green bars), 31 to 60 foci (yellow bars), 61 to 90 foci (red bars), and >91 foci (brown bars) at each time point. The
y axis indicates the percentage of each category at each
time point. For Mre11, only large, well-distinguished foci were scored
(e.g., the nucleus marked with an arrowhead in panel D was scored as
negative for Mre11 foci). Thus, the number of Mre11 foci may have been
underestimated. Note that 53BP1 foci form early at 30 min
postirradiation, when Mre11 foci were not observed at all.
|
|
In Fig. 5G, the number of 53BP1 foci (upper graph)
or Mre11 foci (lower graph) per nucleus were counted for 50 nuclei at
each time point after X-ray irradiation using a confocal microscope and
categorized as indicated, and the percentages of each category were
plotted. The average number of 53BP1 foci in untreated HT1080 cells was
12.9 ± 10, which was higher than the number in Xenopus XTC-2 and AT cells for unknown reasons (see Table 1). Some HT1080 cells
had very few foci and some had more (5 to 30 foci/nucleus) under normal
conditions (see Fig. 8D). At 30 min postirradiation, the number of
53BP1 foci increased to 62 ± 24. In contrast, at this early stage
of postirradiation Mre11 did not show discrete focal distribution (Fig.
5G, lower graph) (at 30 min there were no countable foci). This result
appeared to be consistent with the previous observation by Nelms et al.
(38), who had shown that Mre11 is recruited to chromatin
in the nuclear volume, where the DNA lesions and repair synthesis occur
as early as 30 min after the irradiation though the protein does not
show focal distribution under a standard microscope. As reported,
discrete Mre11 foci were observed only at later stages of
postirradiation (9, 15, and 24 h) (33). Here we
scored only large discrete Mre11 foci. Since Mre11 staining had a
higher overall chromatin signal than did 53BP1 staining, it was more
difficult to count convincingly the smaller Mre11 foci (e.g., the
nucleus marked with an arrowhead in Fig. 5D was scored as negative for
Mre11 foci; note that the counting was performed with cells stained
singly either with anti-53BP1 or with anti-Mre11 antibody). So in Fig.
5G, the number of Mre11 foci was likely to be underestimated when
compared with the number of 53BP1 foci, which always showed more
contrast than did the overall chromatin staining. Thus, in human cells,
53BP1 focus assembly was induced at quite an early stage in response to
DNA damage.
Hyperphosphorylation of XL53BP1 in cells
irradiated with X rays.
We examined whether XL53BP1 was
phosphorylated in response to ionizing irradiation, as this has been
reported for other checkpoint proteins like BRCA1, Crb2, Nbs1, and
Rad9sp (10, 31, 65, 67). XL53BP1 from cells
irradiated with X rays migrated more slowly than the XL53BP1 from
untreated cells on SDS-polyacrylamide gel electrophoresis (Fig.
6A, lanes 2 and 3). This retardation was
due to phosphorylation, since this slower migration was eliminated by
treatment of the immunoprecipitated XL53BP1 with protein phosphatase
(Fig. 6A, lane 4). The shift was already visible at 30 min
postirradiation (lanes 5 and 6; see also Fig. 6C, lanes 1 and 2, for
human cells) and became more pronounced at 3 h (Fig. 6B, lanes 1, 4, and 7). Note that there was no significant increase in the XL53BP1
levels after the X-irradiation.
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FIG. 6.
Phosphorylation of XL53BP1 in cells irradiated with X
rays. (A) XL53BP1 was immunoprecipitated from XTC-2 cells either
untreated (lanes 1 and 3; X ray) or exposed to X rays (lanes 2 and
4; + X ray) at 2 h postirradiation. Half of the samples were
treated with protein phosphatase (lanes 1 and 4; + PPase). The proteins
were run on a gel and immunoblotted with anti-XL53BP1 antibodies.
XL53BP1 of irradiated cells migrated more slowly than that of
nonirradiated cells (lanes 2). This retardation was lost if the sample
was phosphatased (lane 4). Lanes 5 and 6 indicate that the band
retardation was already seen at 30 min postirradiation. (B) Caffeine
blocks the phosphorylation of XL53BP1. XTC-2 cells were either
untreated (lanes 7 to and 9) or exposed to X rays (lanes 1 to 6) in the
absence of drugs (lanes 1, 4, and 7) or in the presence of 16 mM
caffeine (lanes 2, 5, and 8) or 23 µM wortmannin (lanes 3, 6, and 9).
Extracts were prepared from irradiated cells at 30 min (lanes 1, 2, and
3) and at 3 h (lanes 4 to 6) post-X-ray exposure. The extent of
the band retardation was significantly reduced in the presence of
caffeine (e.g., compare lanes 4 and 5). Wortmannin had a similar effect
but with lower efficiency (lane 6). The same amount of protein was
loaded per slot. The lower bands were degradation products of XL53BP1.
(C) AT cells show a reduction in 53BP1 phosphorylation in response to
X-ray irradiation. Extracts were prepared from untreated cells (lanes
1, 5, and 9) or from cells irradiated with X rays, at 30 min (lanes 2 and 8), at 1 h (lanes 3 and 7), and at 3 h (lanes 4 and 6)
postirradiation. In control ATM+ HT1080 cells (lanes 1 to
5), 53BP1 showed slower migration after X-ray irradiation (lanes 2 to 4). In AT cells that are
ATM kinase defective (lanes 6 to 9), the retardation was greatly
reduced and the 53BP1 band showed only a slight retardation at 1 and
3 h compared with that of the untreated control (compare lanes 6 and 7 to 9). 53BP1 from the untreated HT1080 cells ran slightly more
slowly than that from AT cells for unknown reasons. Samples were loaded
in an order to see the shifted and the nonshifted bands next to each
other.
|
|
Next we investigated the effects of known inhibitors of
ATM-related kinases on the hyperphosphorylation of XL53BP1
induced by X-ray irradiation. XTC-2 cells were preincubated in
the presence of either 16 mM caffeine or 23 µM wortmannin for 1 h and then irradiated with X rays. At 30 min and at 3 h
postirradiation, extracts were prepared and run on a SDS-polyacrylamide
gel for immunoblotting (Fig. 6B). Caffeine was shown to be a potent
ATM-related kinase inhibitor (2, 16, 49). The 50%
inhibitory concentrations of ATM, ATR, and DNA-PK to caffeine
were 0.2, 1.1, and 10 mM, respectively (49). In the
presence of 16 mM caffeine, most of the activities of ATM-related
kinases were expected to be blocked. Wortmannin irreversibly inhibits
certain members of the PI3K family, and 23 µM wortmannin blocks the
activities of ATM and DNA-PK but not that of ATR in intact cells
(50) (in cells, 50% inhibitory concentrations of the
kinases were 5.8, 3.6, and 100 µM, respectively). We found that the
slower migration of XL53BP1 was almost completely eliminated in the
extracts prepared from cells irradiated in the presence of 16 mM
caffeine (Fig. 6B, lanes 2, 5, and 8). Wortmannin showed a similar
effect but was less effective (Fig. 6B, lanes 3, 6, and 9). In the
presence of 23 µM Wortmannin, XL53BP1 migrated slower than that from
cells without irradiation or from caffeine-treated cells but faster
than that from cells that had not been treated with inhibitors after
X-ray irradiation (Fig. 6B, lanes 3, 6, and 9). However, it was
possible that the inhibitory effects of these drugs on the
phosphoryaltion of XL53BP1 were not necessarily through ATM-related
kinases, especially given the relatively high concentration of caffeine used.
To investigate further the possible implication of ATM kinase, we
examined the band retardation of 53BP1 before and after the irradiation
of AT cells that were deficient for ATM kinase. The extent of the 53BP1
band retardation was significantly reduced, although the band shift was
not completely abolished (Fig. 6C, lanes 6 to 9; compare with the
results for control HT1080 cells, which are ATM+). Due to
technical reasons, the amount of total protein we could load per slot
for AT cells was approximately half that of HT1080 cells; therefore,
the 53BP1 bands were slightly fainter in AT cell samples. These results
suggested that ATM, and possibly its related kinases, were implicated
in the hyperphosphorylation of XL53BP1 in response to the DNA damage
induced by X-ray irradiation.
Caffeine inhibits the focal redistribution of XL53BP1 in cells
irradiated with X rays.
Given that the postirradiation
phosphorylation of XL53BP1 was reduced in the presence of either
caffeine or wortmannin, we were interested in examining whether the
focal redistribution of XL53BP1 would also be affected by the presence
of these drugs during damage induction. XTC-2 cells were treated as
described above, fixed, and stained for XL53BP1 (Fig.
7). In control cells without inhibitor
treatment, the focal redistribution of XL53BP1 was already visible at
30 min postirradiation, and at 3 h, it was prominent (Fig. 7A and
B, respectively). However, in the presence of 16 mM caffeine, the
protein stayed distributed mostly homogeneously over the chromatin even
after 3 h postirradiation and the numbers of 53BP1 foci assembled
were significantly lower (Fig. 7C and D). It is worth noting that this
concentration of caffeine was four times higher than that usually
required to block the DNA damage checkpoint (51). At a
lower concentration of caffeine (i.e., 4 mM), we did not observe any
delay of 53BP1 focus formation after X-ray irradiation (data not
shown). Wortmannin showed a moderate effect, and the focal
redistribution of XL53BP1 appeared to be slightly delayed in the early
stages (Fig. 7E; see also Table 1) of postirradiation. Later, at 3 h postirradiation, the assembly of XL53BP1 foci was nearly as efficient
as that of the no-drug control (F).
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FIG. 7.
XL53BP1 focus formation is diminished or delayed in the
presence of caffeine or wortmannin, respectively. Cells were treated as
described for Fig. 6. XTC-2 cells were exposed to X rays either in the
absence of any drugs (A and B) or in the presence of 16 mM caffeine (C
and D) or 23 µM wortmannin (E and F) and fixed at 30 min (A, C, and
E) or at 3 h (B, D, and F) postirradiation for XL53BP1 stain.
|
|
A slight delay of 53BP1 focal redistribution was also observed in AT
cells (Fig. 8). In HT1080
(ATM+) cells, 53BP1 focus formation was clearly observed
1 h after X-ray irradiation (Fig. 8E). Whereas, in AT
(ATM
) cells at 1 h postirradiation, fewer and less
distinct 53BP1 foci had formed (Fig. 8B). By 3 h postirradiation,
the AT cells had managed to assemble discrete 53BP1 foci (Fig. 8C). We
scored the number of countable 53BP1 foci per nucleus by optical
sectioning with a confocal microscope (Table
1). Counting was performed by two
independent investigators, and we obtained consistent results. At 30 min postirradiation, more than 60 foci were counted on average in
HT1080 nuclei. In contrast, only 23.5 foci were counted per AT cell
nucleus on average at 30 min. After 3 h we did not observe a
significant difference in numbers of foci between HT1080 and AT cells.
A slight delay in XL53BP1 focus formation was also observed in XTC-2
cells in the presence of wortmannin (30 versus 54 foci in the no-drug
control after 30 min). These results suggested that ATM kinase might be
implicated in the rapid response of 53BP1 focus formation after
ionizing irradiation; however, the kinase was not essential for focal
assembly.
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|
FIG. 8.
AT cells show a slight delay in 53BP1 focus formation in
response to X-ray irradiation. AT cells (A to C) or HT1080 cells (D to
F) were either untreated (A and D) or exposed to X rays, fixed at
1 h (B and E) or at 3 h (C and F) postirradiation, and
stained for 53BP1.
|
|
View this table:
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|
TABLE 1.
Slight delay in 53BP1 focus formation in AT cells and in
XTC-2 cells in the presence of wortmannin after X-ray exposure
|
|
| |
DISCUSSION |
53BP1, a member of the BRCT protein family, is hyperphosphorylated
and relocalizes to a number of nuclear foci in response to DNA damage.
These foci also contain the Mre11-Rad50-Nbs1 complex. 53BP1, however,
concentrates in foci in 30 min, which is significantly earlier than the
time any obvious concentration of Mre11 occurs in the postirradiation
period (9 to 15 h after irradiation [33]). There
were several proteins that coimmunoprecipitated with 53BP1 (Fig. 1A).
However, we detected neither p53 nor Mre11 in the 53BP1 immunoprecipitate under the experimental conditions (data not shown).
The assembly of 53BP1 foci is not cell cycle stage dependent. In
contrast, Rad51 and BRCA1, which also change their subnuclear localization after DNA damage, show a focal distribution in S phase and
disperse homogeneously over the nucleoplasm after genotoxic treatments
(52, 64). Ionizing irradiation induces Rad51 and BRCA1
focal assembly in cells presumed to be in either G1 or G2 (15,
59, 64), whereas irradiation-induced 53BP1 foci occur in almost
all cells except those in mitosis. Rad51, Mre11, or BRCA1 foci are
observed in a subset of cells after irradiation (10 to 40%, depending
on the protein, cell type, and cell cycle stage [33, 44,
64]).
The histone H2A variant H2AX, which makes up 20% of the total H2A in
human cells, is phosphorylated at Ser 139 in response to dsDNA breaks.
H2AX phosphorylation has been demonstrated to occur at the sites of
lesions by scissoring laser treatment (46, 47). Recently,
a comprehensive study has shown that the different types of
damage-induced foci, including BRCA1, Rad51, and the Mre11-Rad50-Nbs1
complex foci, all originate from -H2AX foci at certain stages of the
postirradiation period (44). The associations appear to
follow a sequential order, and some of them might also be cell cycle
stage dependent. The focally distributed H2AX phosphorylated at Ser 139 (called -H2AX) appears immediately after irradiation, peaks by 10 min, and then gradually decreases and almost disappears after 4.5 h (46, 47). Kinetically, the appearance of 53BP1 foci and
53BP1's hyperphosphorylation occur slightly later than the appearance
of foci and H2AX's hyperphosphorylation of H2AX but earlier than
with the other types of damage-induced nuclear foci. At 30 min
postirradiation the focal distribution and the phosphorylation of
XL53BP1 are not at their maxima (Fig. 6 and 7). This result might be
reasonable since 53BP1 needs to be recruited to the foci after DNA
damage and, in contrast, since H2AX is already there at the dsDNA
breaks. More than half of the dsDNA breaks are rejoined in an order of
minutes, and the rest persist for several hours (26, 39).
53BP1 foci might be implicated in the repair and/or checkpoint control
associated with the latter.
53BP1 is hyperphosphorylated in response to ionizing irradiation, and
this phosphorylation is significantly reduced in AT cells which are
deficient in ATM kinase (Fig. 6C). The data obtained with the
inhibitors of ATM-related kinases are consistent with the AT cell
results (Fig. 6B). These results suggest that ATM-related kinases are
involved in the phosphorylation of 53BP1 in response to ionizing
irradiation. Interestingly, caffeine inhibits 53BP1 phosphorylation
more efficiently than wortmannin. This is also true for the suppressive
effects of caffeine and wortmannin on the relocalization of 53BP1:
caffeine blocks and wortmannin slightly delays 53BP1 focus formation
(Fig. 7 and Table 1). We observed a slight delay in 53BP1 focal
assembly in AT cells after irradiation (Fig. 8 and Table 1). This
suggests that ATM kinase might be involved in the rapid response of
53BP1 relocalization to ionizing irradiation but that it is not
essential for formation of the foci. Mre11/Rad50 focus formation is
reduced in AT cells but not completely abolished (33).
BRCA1 focus formation is not different in wild-type cells and in AT
cells (10). ATM, ATR, and DNA-PK might have overlapping
roles in phosphorylation and in focus formation. During our paper's
revision, Xia et al. published a paper showing that ATM kinase
phosphorylates XL53BP1 in vitro, which is consistent with our
observation of the inhibitors and AT cells (66).
Our results suggest that the formation of 53BP1 foci is controlled
through phosphorylation of the protein. In budding yeast, accumulating
evidence implicates phosphorylation-regulated protein-protein interactions in the cellular response to DNA damage. dsDNA breaks induce relocalization of Ku, Rap1, and SIR proteins, which are normally
associated with telomeres, to the sites of the lesion, and this process
is dependent on MEC1sc, an ATM-related kinase, and
Rad9sc, a BRCT protein (32, 36).
Rad9SC protein multimerizes through its BRCT domain, and
the interaction occurs with higher affinity after DNA damage
(56). The FHA domain of Rad53sc physically
interacts with phosphorylated forms of Rad9sc (12,
14, 57, 61). Given the fact that there is no evidence for the
presence of an active transport system in the nucleus at the moment and
that RNA and protein factors move by diffusion through the
interchromatin space (see reference 30), it might be
reasonable to speculate that the assembly and disassembly of repair and
checkpoint protein foci are regulated through changing of the
affinities of protein-protein interactions by phosphorylation (see also
reference 44).
The results presented here implicate 53BP1 in DNA damage repair or
checkpoint control in vertebrate cells; however, direct evidence is
still missing. A genetic approach (i.e., disruption of the 53BP1 gene
in DT40 or ES cells) will be required to investigate these
possibilities directly.
| |
ACKNOWLEDGMENTS |
We are grateful to Steve B. Coade for AT cells, Sigenobu Tone for
the BrdU labeling protocol, and Mitsuhiro Yanagida for his advice. We
thank Kevin Hardwick, Ciaran Morrison, Takashi Toda, and Bill Earnshaw
for comments on the manuscript. We also thank colleagues in the ICMB
for discussion and support.
The Wellcome Trust supported this work.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Wellcome
Trust Center for Cell Biology, Institute of Cell & Molecular Biology, University of Edinburgh, Edinburgh EH9 3JR, United Kingdom. Phone: 44-131-650-7087. Fax: 44-131-650-8650. E-mail:
Y.Adachi{at}ed.ac.uk.
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Abstract
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