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Molecular and Cellular Biology, October 2000, p. 7450-7459, Vol. 20, No. 20
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Tumor Suppressor p53 Is Required To Modulate
BRCA1 Expression
Paz
Arizti,1
Li
Fang,2
Iha
Park,1
Yuxin
Yin,3
Ellen
Solomon,4
Toru
Ouchi,2
Stuart A.
Aaronson,2 and
Sam W.
Lee1,*
Department of Medicine, Harvard Medical
School and Beth Israel Deaconess Medical Center, Harvard Institutes of
Medicine, Boston, Massachusetts 021151;
The Derald H. Ruttenberg Cancer Center, The Mount Sinai Medical
School, New York, New York 100292;
Department of Molecular Biology, Princeton University,
Princeton, New Jersey 085443; and
Division of Medical and Molecular Genetics, UMDS, Guy's
Hospital, London SE1 9RT, United Kingdom4
Received 14 June 2000/Returned for modification 17 July
2000/Accepted 21 July 2000
 |
ABSTRACT |
Individuals carrying mutations in BRCA1 or
p53 genes are predisposed to a variety of cancers, and both
tumor suppressor genes have been implicated in DNA damage response
pathways. We have analyzed a possible functional link between
p53 and BRCA1 genes. Here we show that BRCA1
expression levels are down-regulated in response to p53 induction in
cells that undergo either growth arrest, senescence, or apoptosis.
Physiological stimuli, such as exposure to DNA-damaging agents, also
result in negative regulation of BRCA1 levels in a p53-dependent manner
prior to causing cell cycle arrest. Nuclear run-on experiments and
luciferase reporter assays demonstrate that the changes in BRCA1
expression are mainly due to transcriptional repression induced by p53.
In conclusion, the data show that BRCA1 expression levels are
controlled by the presence and activity of wild-type p53 and suggest
the existence of an intracellular p53/BRCA1 pathway in the response of
cells to stress conditions.
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INTRODUCTION |
p53, the protein product of a tumor
suppressor gene, has been implicated in the control of cell
proliferation and tumor progression, as well as in the maintenance of
genome integrity in response to DNA-damaging events (1, 28,
29). Deletion or inactivation of the p53 gene is observed in more
than half of human cancers (23). p53 is induced in response
to suboptimal growth conditions (DNA damage, hypoxia, heat, starvation,
etc.) and acts as an "emergency brake" to trigger cells to
reversible or irreversible growth arrest or even to apoptosis (8,
15, 20, 38, 54, 62), thus protecting the genome from accumulating
an excess of mutations. Once active, p53 binds specifically to p53
response elements and transactivates the expression of genes such as
those encoding mdm2, GADD45, p21 (Waf1 or Cip1), bax, PAG608, cyclin G,
and IGF-BP3 (1, 26, 28, 29). The p53 protein has also been
shown to repress transcription driven from certain viral promoters, as
well as from cellular genes. Genes encoding RB, c-fos, MAP4, presenilin, and DNA topoisomerase II
are among the characterized p53-repressed genes (13, 38, 42, 50, 58).
Given the complexity and importance of the cellular response to p53,
its expression must be tightly regulated. The ubiquitin-mediated proteolysis pathway is, at least in part, responsible for maintaining p53 protein levels at a low concentration in normal cells
(9). p53 levels and activity are also under tight control by
upstream effectors such as the DNA-protein kinase family
(60), negative autoregulation (34),
phosphorylation (24, 25, 55, 59), and other cellular
proteins such as mdm2 and CBP/p300 (17, 30, 32, 49, 57).
BRCA1 is also a tumor suppressor gene. Mutations in the
BRCA1 gene account for about 50% of inherited breast cancer
cases and 80% of families predisposed to breast and ovarian cancers (5, 39). In fact, there are interesting parallels between p53 and BRCA1. BRCA1, like p53, is a cell cycle-regulated nuclear phosphoprotein (27, 43, 56) and has also been implicated in
DNA damage response and repair pathways. In addition, BRCA1 interacts with some of the major proteins involved in eukaryotic double-strand break repair and homologous recombination (46, 47) and participates, directly or indirectly, in
transcription-coupled repair of oxidative DNA damage (16, 35,
45). Both p53 and BRCA1 are posttranslationally altered by
phosphorylation in response to DNA damage (47, 49, 51, 56).
Moreover, BRCA1 acts as a transcription factor, although this property
is less well characterized than for p53. In artificial systems, BRCA1
can activate the p21 gene and other genes containing p53-responsive
elements (37, 52, 66) or trigger cells to undergo apoptosis
(21). BRCA1 is a very complex protein that also seems to be
regulated by phosphorylation (47, 56), by its interacting
proteins (7, 48, 61, 67), and probably through its complex
promoter (63). Nevertheless, little is known about BRCA1
activators and regulators. In addition, p53 coimmunoprecipitates with
BRCA1 (6, 37, 53, 66) and BRCA1
/ embryos are
partially rescued by null mutation of the p53 gene (19, 31).
In view of these similarities between p53 and BRCA1, we investigated
how BRCA1 responds to p53 activation. We show here that exogenously
induced p53 causes down-regulation of BRCA1 levels. In response to
DNA-damaging agents, both BRCA1 mRNA and protein levels decrease prior
to cell cycle arrest in a p53-dependent manner. Finally, we also
demonstrate that BRCA1 transcription is repressed by wild-type (wt)
p53. These findings indicate that, while present, p53 regulates BRCA1
expression in responding to stress growth conditions.
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MATERIALS AND METHODS |
Cell culture.
Normal human mammary epithelial cells (hNMEC)
were isolated from reduction mammoplasties and were maintained in
DFCI-1 complete medium (3) for a few passages (i.e., five or
six population doublings). All other cell lines were maintained in
Dulbecco's modified Eagle's medium containing 10% fetal bovine serum
plus antibiotics. For EJ-p53 and EJ-CAT cells, the medium contained 1 µg of tetracycline (tet)/ml. Removal of tet resulted in p53 induction, as previously described (54). Primary mouse
mammary epithelial cells (mNMEC) were isolated from mammary glands of 129/Sv (wt p53; Jackson Laboratories) or 129 trp53tmlTyj
(p53 knockout; Jackson Laboratories) mice, as previously described (41).
DNA damage treatment.
Cells were plated in 100- or
150-mm-diameter tissue culture dishes and grown to 60% confluence.
Mitomycin C (MMC; Sigma) was added to cultures at 10 µg/ml, and cells
were harvested after treatment at time points over 24 h.
Actinomycin D (Act D; Sigma) was added to cultures at a final
concentration of 10 ng/ml, and cells were harvested over 48 h
after treatment. For gamma irradiation, cells were exposed to 20 Gy in
a mark I137 Cs source irradiator and allowed to recover for
up to 12 h. After treatment, cells were collected and processed
for Western, Northern, or fluorescence-activated cell sorter (FACS) analyses.
Western and Northern blot analyses.
Samples were adjusted
for equal protein loading and separated on 5 (for BRCA1 analysis) or
12% gels under reducing conditions. Western blot transfer onto
nitrocellulose was carried out, and blots were probed with antibodies
against BRCA1 (Ab17F8; Gene Tex, and MS110 [Ab-1]; Oncogene Science),
wt p53 (Ab-6; Oncogene Science), and 
-actin (clone AC-15; Sigma).
Bands were detected using the ECL chemiluminescence detection method
(Amersham) and exposed on X-ray film. For Northern blot analysis, total
RNA was isolated after lysis of cells in guanidine-HCl and
centrifugation on cesium chloride cushions. Then 20 µg of total RNA
per sample was denatured, electrophoresed through a 0.8%
agarose-formaldehyde gel, and transferred by capillarity onto a nylon
membrane. BRCA1, p21, mdm2, and 36B4 probes were labeled with
32P by using the randomly primed DNA labeling technique.
Blots were exposed on X-ray film after being washed. In all cases, the
films were scanned (ScanJet IIcs; Hewlett-Packard), analyzed using
Adobe Photoshop, and quantified using IPLab gel software.
Nuclear run-on assay.
Nuclear run-on analyses were performed
as described previously (2). Briefly, filters containing 300 ng of the purified cDNA inserts were prepared using a slot blot
apparatus, and DNA was immobilized on the filters at 80°C for 1 h. Nuclei were isolated from 107 EJ-p53 cells grown in the
presence or absence of tet for 24 h. Then, nuclei were frozen in
liquid nitrogen. Transcription in isolated nuclei was performed; thawed
nuclei were incubated with nucleotides plus 8 µl of 10-mCi/ml
[-32P]UTP (800 Ci/mmol) for 30 min at 30°C and
treated with RNase-free DNase I, and proteinase K treatment followed.
Synthesized RNA was then extracted with phenol-chloroform and
precipitated with ethanol. One milliliter of RNA solution containing
107 cpm was used to hybridize each of the cDNA-immobilized
strips for 36 h at 65°C with shaking. Filters were washed two
times at 65°C in 2× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium
citrate) for 1 h and another time in 2× SSC containing 10 mg of
RNase A/ml at 37°C for 1 h. Quantification of the signal was
performed on a PhosphorImager (Molecular Diagnostics) using IPLab gel software.
Plasmids, transfections, and enzymatic assays.
Plasmids
pGL3-basic vector and pGL3-control vector (pGL3-CV) were obtained from
Promega. Constructs pGL3-I through pGL3-V derive from pGL3-basic and
correspond to plasmids pGL1, pGL2, pGL5, pGL6, and pGL7 in the paper by
Xu et al. (63), respectively. pGL3-I-del was constructed by
inserting a 580-bp SmaI fragment from pGL3-I into the pGL3-I
vector after removal of the 856-bp HindIII-NruI fragment. pGL3-SV40/TATA-like,
pGL3-SV40/mutTATA-like, and pGL3-SV40-ERE/AP1 were constructed by
inserting a 50-bp KpnI/BamHI fragment containing
a TATA-like sequence within the BRCA1 promoter, a mutated TATA-like
sequence, or an ERE/AP1 region, respectively, into pGL3-CV. In all
cases, two 38-base ordered oligonucleotides containing complementary 3'
ends were hybridized, filled in with Klenow fragments, and digested
with KpnI/BamHI before being introduced into the
equally digested pGL3-CV. EJ-p53 cells were grown to 60% confluence in
60-mm-diameter dishes 24 h prior to calcium phosphate
transfection. DNA mixtures contained 3 µg of pRSV-LacZ and 5 µg of
each of the test plasmids. At 16 h after transfection cells were
subjected to a 20% glycerol shock for 1 min, washed three times with
phosphate-buffered saline, (PBS) and incubated in a CO2
incubator for 36 to 48 h in fresh media with and without tet.
Samples were then collected, and luciferase and -galactosidase activities were measured. Luciferase assays were performed using a
Promega kit by following the manufacturer's instructions. Briefly, cells from 60-mm-diameter dishes were lysed in 250 µl of luciferase lysis buffer containing 1% Triton X-100 as the detergent and incubated at room temperature for 15 min and lysates were transferred to microcentrifuge tubes. After the addition of 100 µl of luciferase assay reagent (which contains luciferin, ATP, and coenzyme A), luciferase activity on 25 µl of each sample was measured by using a
luminometer (Monolight 2010; Analytical Luminescence Laboratory). The
same lysates (50 µl of each sample) were used to measure the -galactosidase activity. The substrate
o-nitrophenyl--D-galactopyranoside (4 mg/ml;
Sigma) was added, and reactions were allowed to proceed until a light
yellow color developed. Reactions were stopped with 1 M sodium
carbonate, and the absorbance at 420 nm was measured. Data obtained for
-galactosidase activities, representing the efficiency of
transfection, were used to normalize luciferase measurements, and the
transactivation activity of each test construct was calculated relative
to the pGL3-basic vector (whose activity was arbitrarily defined as 1).
Each construct was analyzed in triplicate and in three independent
experiments; thus the relative promoters' activities represent the
mean values ± standard deviations.
FACS analyses.
Cells treated with DNA-damaging agents were
washed with PBS three times and collected by centrifugation into
microcentrifuge tubes. Ice-cold 50% ethanol was then added dropwise
over the pellets (106 cells/ml), and these were kept on ice
for at least 60 min. After fixation, cells were permeabilized (0.5%
Triton X-100 and 230 µg of RNase A/ml in PBS) and propidium iodide
was added to 50 µg/ml. Samples were kept in the refrigerator at least
30 min and analyzed by flow cytometry (Becton Dickinson; FACScan) using
a 488-nm excitation light and collecting fluorescence above 620 nm.
Data were then processed with VERITY ModFit, version 5.2, for Microsoft
Windows software for DNA distribution analysis.
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RESULTS |
Decreased expression of BRCA1 following wt p53 induction.
We
attempted to determine if expression of wt p53 influenced the level of
BRCA1 expression. EJ-p53 cells, a tet-regulatable p53 cell line
previously described (54), was used to study the response of
BRCA1 to p53 induction. Removal of tet from the culture media of EJ-p53
exponentially growing cells resulted in the expression of wt p53
protein as early as 6 h, with peak levels observed by 48 h
(Fig. 1A). Under these conditions, BRCA1
mRNA and protein levels were readily detectable in the presence of tet
but decreased markedly to ~24 and ~7%, respectively, following wt
p53 induction (Fig. 1A). The induction of p53 also caused a slight
shift in the BRCA1 protein mobility (Fig. 1A). This reduction of BRCA1 levels following p53 activation was in striking contrast to the induction of expression of well-known p53 target genes, including those
encoding p21 (Fig. 1A) and mdm2 (data not shown). As a control, EJ-CAT
cells, in which EJ cells were stably transfected with a tet-inducible
chloramphenicol acetyltransferase (CAT) vector, did not respond to the
tet removal, p53 remained undetectable, p21 was not induced, and BRCA1
levels were unchanged (Fig. 1A). This result indicated that tet itself
or the overexpression of the CAT gene had no effect on BRCA1 expression
levels and suggested that down-regulation of BRCA1 was specific to the
p53 induction. Moreover, p53 expression was reversible, with no p53
detected in EJ-p53 cells within 24 h after tet readdition (Fig.
1A), which indicates that the system is tightly regulated. This absence
of p53 after tet readdition was immediately followed by a decrease in
p21 levels, and recovery of BRCA1 mRNA and protein to basal levels was
also observed (Fig. 1A).
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FIG. 1.
Down-regulation of BRCA1 by wt p53 overexpression. (A)
Repression of BRCA1 mRNA and protein following p53 induction in a
tet-regulated system (EJ-p53). RNA and protein extracts were collected
at different time points from EJ-p53 cells grown in the presence (+) or
absence ( ) of tet. In lane 1 +1, cells were grown in the absence
of tet for 1 day to allow expression of p53, and then tet was added for
another day before RNA and protein were collected. The Northern blot
was consecutively hybridized with probes for BRCA1, p21, and 36B4.
Western blotting was performed, and blots were immunoblotted with BRCA1
(antibody Ab17F8; GeneTex), p53, and -actin antibodies. EJ-CAT cells
were used as the negative control. (B) Temperature shift induces
decreased BRCA1 mRNA levels in cell lines containing a
temperature-sensitive p53 mutant (Vm10 and VhD). The parental murine
cell line 10.1, which is null for p53, does not show down-regulation of
BRCA1 following the temperature shift.
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To verify that the observed p53-mediated repression of BRCA1 expression
was indeed a general phenomenon and not due to growth
arrest triggered
by p53 overexpression in one cell type (EJ-p53),
another p53-inducible
system was used. VhD and Vm10 cell lines
are immortalized mouse
embryonic fibroblast cells containing a
temperature-sensitive p53
mutant (Val-to-Ala mutation in codon
135). These lines express a
nonfunctional p53 protein at 37 to
39°C that becomes fully functional
at 32°C. VhD cells undergo
reversible G
1 arrest in a
p53-dependent manner at 32°C, while
the Vm10 cell line, which
expresses tsp53 and the c-myc oncogene,
undergoes apoptosis at 32°C
(
8,
62). In contrast, p53 induction
in EJ-p53 triggered
cells to undergo irreversible growth arrest
or senescence
(
54). In the two cell lines containing tsp53,
the
temperature shift from 38 to 32°C caused a marked reduction
of BRCA1
mRNA expression within 24 h and was accompanied by the
induction
of the p53 target genes encoding p21 and mdm2 (Fig.
1B). However, the
p53-null parental line of VhD and Vm10 cells
(10.1) remained unchanged
following the temperature shift: p21
and mdm2 were not induced, and the
levels of BRCA1 remained constant
(Fig.
1B), similar to the expression
levels in VhD and Vm10 cells
cultured at 38°C. These results
demonstrate that p53-mediated
down-regulation of BRCA1 is a generally
occurring
phenomenon.
Down-regulation of BRCA1 following DNA damage is p53
dependent.
It is now well established that p53 functions to
integrate cellular responses to stress such as DNA damage. p53 becomes
activated following physiological stimuli such as DNA damage, leading
to transcriptional activation of its target genes. Therefore, we analyzed whether BRCA1 expression could be regulated by the
accumulation of p53 in response to DNA damage. First, hNMEC and a human
breast cancer cell line (MCF7), both containing wt p53, were treated with 20 Gy in a gamma irradiator with a mark I135 Cs
source. In both cell types, treatment resulted in a consistent and
stepwise decrease in BRCA1 transcript levels, whereas the expression of
the 36B4 message remained unchanged (Fig.
2A). The results from several independent
Northern experiments indicate that BRCA1 mRNA levels were reduced by
approximately 80% as early as 12 h after treatment in both cells.
p53 activation was monitored at the protein level, as well as by
transactivation of the p53 target gene, the p21 gene (Fig. 2A). Under
the same conditions, the expression of the BRCA1 protein was measured
by Western blot analysis. A dramatic disappearance of BRCA1 protein
expression following p53 induction was observed, while -actin
expression remained constant (Fig. 2A). Of note, prior to its
disappearance, the BRCA1 protein in gamma-irradiated cells was found to
migrate at a slower rate than that from untreated control cells. This altered BRCA1 gel mobility was probably indicative of BRCA1
posttranslational modifications, such as phosphorylation, as other
research groups have already indicated (10, 47, 56).
However, irradiated T47D cells, a human breast carcinoma cell line
which contains a mutant form of p53, did not show down-regulation of
BRCA1 mRNA or protein levels or protein modification (not shown).
Therefore, our data indicate that, following physiological induction of
p53, the BRCA1 protein is most probably phosphorylated and then both mRNA and, to a further extent, protein levels of BRCA1 are diminished in a p53-dependent manner.
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FIG. 2.
Decrease of BRCA1 expression in response to DNA damage
requires wt p53. (A) Northern and Western blot analysis of BRCA1
expression following gamma irradiation. hNMEC and MCF7 cells were
exposed to 20 Gy of gamma irradiation, and RNA or total proteins were
collected at the indicated times following irradiation. After DNA
damage exposure, the BRCA1 protein mobility was retarded and then the
protein levels decreased. BRCA1 mRNA expression was also reduced.
Western blots were immunoblotted with BRCA1 antibody Ab17F8 (GeneTex).
(B) Down-regulation of BRCA1 expression in wt p53 cell lines following
Act D treatment. A human colon cancer cell line containing wt p53
(HCT116 cells) and two other cell lines containing mutant (mut) p53
(PC3 and EJ) were treated for different time periods with 10 ng of Act
D/ml, and then RNA and protein were collected. In this case, Western
blots were immunoblotted with BRCA1 Ab1 from Oncogene (clone MS110).
(C) Northern blot analysis of BRCA1 in several cell lines following
treatment with MMC (10 µg/ml). BRCA1 expression levels were reduced
only in the wt p53 cell lines. (D) Enhanced basal levels of BRCA1 in
p53/ cells compared to those in p53+/+
cells. mNMEC from p53 knockout mice or their wt equivalent were
isolated and treated with Act D for different time periods; then
Northern blot analysis was performed. p53 null cells do not reduce
their BRCA1 expression levels in response to Act D treatment.
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To further confirm the decrease in BRCA1 expression following DNA
damage and to verify that the response was p53 dependent,
several cell
lines differing in their p53 status were treated
with different
DNA-damaging agents, such as Act D (Fig.
2B), MMC
(Fig.
2C),
doxorubicin, and UV irradiation (not shown). Exposure
to these agents
also resulted in a marked reduction of BRCA1 expression
at the mRNA and
protein levels in cells containing wt p53 (Fig.
2B and C). We noted
further that a slower-migrating BRCA1 band
from MCF7 cells appeared as
early as 1 h after MMC treatment (data
not shown). In contrast,
BRCA1 expression levels remained unchanged
when p53 mutant cell lines
were exposed to DNA-damaging agents
(Fig.
2B and
C).
To assess the importance of p53 itself in controlling BRCA1 expression
in a noncancerous context, we examined BRCA1 levels
in mNMEC isolated
from p53 knockout mice or their wt equivalent.
Northern blot analysis
revealed that endogenous BRCA1 expression
was very elevated in
p53
/ cells compared to that in p53
+/+ cells
(Fig.
2D). BRCA1 basal expression levels were found to
be at least
10-fold higher in the p53 knockout cells. In the presence
of p53, BRCA1
mRNA levels were reduced in response to DNA damage
exposure, but p53
knockout cells failed to show down-regulation
of BRCA1 levels. If
anything, exposure of p53 null cells to Act
D resulted in a slight
induction of BRCA1 mRNA, while p21 and
mdm2 remained almost
undetectable (Fig.
2D). Altogether, these
results show a strong
correlation between p53 status and down-regulation
of BRCA1 and
demonstrate that functional p53 is required for BRCA1
repression to
occur following DNA
damage.
Down-regulation of BRCA1 occurs prior to cell cycle arrest.
It
is well characterized that, following induction and activation of p53,
cells undergo arrest or apoptosis. Thus, it was possible that the
reduction of BRCA1 might be an indirect effect of cell cycle arrest
caused by p53, since BRCA1 is known to be expressed in a cell
cycle-dependent manner. To determine if the observed p53-induced BRCA1
repression was indeed specific, we designed experiments to elucidate
whether the reduced level of BRCA1 resulted from the arrest at
G1 and/or G2/M induced by p53 or occurred prior
to it. Thus, MCF7 cells, which contain wt p53, were exposed to a
DNA-damaging agent (Act D; 10 ng/ml) and harvested at different times
for assessment of BRCA1 mRNA and protein as well as cell cycle analysis
by FACS (Fig. 3). For each time point, levels of BRCA1 expression and cell cycle status in Act D-treated cells
and untreated control cells were compared. As shown in Fig. 3A, more
than 90% of the BRCA1 mRNA and protein disappeared within 12 h
after DNA damage, while cells were still progressing through S phase
with no signs of arrest. At 24 h, expression of BRCA1 was almost
absent, cells were still normally entering into S phase (Fig. 3B), and
no apoptotic cells were present (data not shown). Figure 3C summarizes
the time course of BRCA1 and p53 expression changes following DNA
damage, establishing that down-regulation of BRCA1 expression in
response to p53 induction clearly occurs prior to detectable growth
arrest or apoptosis.
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FIG. 3.
BRCA1 down-regulation in response to DNA damage occurs
prior to cell cycle arrest. MCF7 cells were treated with 10 ng of Act
D/ml, and then RNA and proteins were prepared and cell cycle analysis
was performed at the indicated time points (0, 12, 24, and 48 h).
(A) Reduction of BRCA1 expression following DNA damage as shown by
Northern and Western blot analysis (Ab1-MS110 [Oncogene] was used to
detect BRCA1 protein). (B) Cell cycle analysis of Act D-treated MCF7
cells was performed by FACS. The percentage of cells in each phase of
the cell cycle after DNA damage exposure is indicated. No major changes
were observed for the first day of treatment. Exposure to Act D for
48 h showed a significant reduction of cells in S phase, but no
apoptotic nuclei were observed (data not shown). (C) Summary of the
time courses of BRCA1 and p53 expression changes following DNA damage.
Data in panels A and B were quantified, and the values obtained for the
treated cells with respect to the untreated cells were represented in a
graph form.  , percentage of BRCA1 protein level;  , percentage of
p53 protein level following Act D treatment;  , percentage of the
cells remaining in S phase after Act D treatment.
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Repression of the human BRCA1 gene by wt p53.
In an effort to
determine whether the decrease in BRCA1 mRNA following p53 induction
occurred at the transcriptional or posttranscriptional level, nuclear
run-on assays were performed. Figure 4A
depicts the data from nuclear run-on transcription assays performed on nuclei isolated from EJ-p53 cells maintained with and without tet for
24 h. Following removal of tet the rate of BRCA1 transcription was
decreased to ~40% of the basal level, whereas the rate of transcription from the p21/WAF1 gene, a p53-inducible gene, increased up to ~250%. 36B4 was used as a control, and its rate of
transcription remained unchanged following p53 induction (Fig. 4A). The
nuclear run-on experiment indicates that repression of BRCA1 expression following p53 activation occurs mainly via a decrease of transcription from the promoter of the BRCA1 gene.
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FIG. 4.
Transcriptional repression of BRCA1 by p53. (A) Nuclear
run-on analysis using [-32P]UTP-labeled nuclei from
EJ-p53 cells grown in the presence of tet or in the absence of tet for
24 h (left). Filters used for hybridization contained 300 ng of
purified cDNA inserts from BRCA1, p21, and 36B4. Quantification of
nuclear run-on data relative to those for EJ-p53 cells grown in the
presence of tet is shown at the right. BRCA1 transcription is
significantly reduced in the presence of p53. (B) BRCA1 protein is
destabilized. BRCA1 protein accumulates after inhibition of proteases
when p53 is induced. EJ-p53 cells were cultured in the presence or
absence of tet and treated with the protease inhibitor ALLN (100 µM)
for 24 h. BRCA1 protein was then analyzed from cell extracts by
Western blotting using BRCA1 antibody Ab17F8 from GeneTex, and the
BRCA1 bands were quantified using IPLab gel software. Data obtained
from that quantification, relative to the basal BRCA1 level in the
absence of p53, are shown at the bottom.
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In addition, we have investigated whether the BRCA1 protein is
destabilized in the presence of p53, since a change in protein
metabolism might explain why BRCA1 protein disappears to a greater
extent than BRCA1 mRNA. For EJ-p53 cells, once p53 is active,
BRCA1
protein is down-regulated to ~7% of the basal level, while
mRNA is
down-regulated to only ~24%. So, to further understand
BRCA1 protein
regulation, we treated EJ-p53 with the protease
inhibitor ALLN in the
presence or absence of tet. ALLN treatment
of EJ-p53 cells partially
abrogates p53-induced BRCA1 down-regulation.
Figure
4B shows that BRCA1
protein accumulates faster after inhibition
of proteases in p53-induced
cells and suggests that BRCA1 protein
might be degraded faster in a p53
functional system. The data
demonstrate that the decrease in BRCA1
following p53 induction
occurred mainly at the transcriptional level,
although changes
in protein stability also might play a role in BRCA1
disappearance.
The elucidation of the mechanism whereby p53 down-regulates the
expression of the BRCA1 gene was pursued by reporter analysis
of the
promoter and followed by delineation of those regions necessary
to
confer transcriptional repression. To do so, a luciferase construct
containing the BRCA1 promoter sequence (pGL3-I; Fig.
5A) or a
control
plasmid containing the simian virus 40 (SV40) promoter
(PGL3-CV;
Promega) was transfected into EJ-p53 cells in the presence
or absence
of tet. The luciferase activities shown by these constructs
were then
measured and compared. As shown in Fig.
5A,
induction
of p53 decreased the luciferase
activity under the control of
the BRCA1 promoter by 50% while it had
no effect on the luciferase
activity of the control vector, pGL3-CV.
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FIG. 5.
Analysis of the BRCA1 promoter region(s) necessary to
confer p53-mediated BRCA1 transcriptional repression. (A)
Transcriptional repression of the BRCA1 promoter by p53. (Left)
Schematic diagram of the entire 2.7-kb BRCA1 promoter sequence cloned
upstream of the luciferase reporter gene in the pGL3-basic vector
(construct pGL3-I). pGL3-CV, which contains the luciferase reporter
gene under the control of the SV40 promoter, was drawn for comparison
purposes and used as a control. Luciferase activities obtained for each
construct in EJ-p53 cells in the presence of tet were calculated
relative to that for the pGL3-basic vector (whose activity was
arbitrarily defined as 1). (Right) Luciferase activities obtained
following transient transfection of the constructs. EJ-p53 cells were
transiently transfected with either pGL3-CV or pGL3-I vector and
incubated for 36 h in the presence (p53) or absence (p53+) of
tet. The pRSV-lacZ plasmid was cotransfected with each sample and used
to normalize changes in the transfection efficiency. The y
axis represents the relative luciferase activity after normalization
with respect to EJ-p53 cells grown in the presence of tet, with no p53,
for each construct. (B) A 160-bp sequence within the BRCA1 gene confers
transcriptional repression. (Left) Schematic diagram showing the
deletion constructs of the BRCA1 promoter cloned upstream of the
luciferase reporter gene in the pGL3-basic vector. Solid boxes, BRCA1
exons 1A and 1B and the luciferase gene; promoters and are also
marked. pGL3-II to pGL3-V, several fragments of pGL3-I, as indicated by
the numbering and arrows; numbering of the constructs was done as
described previously (63); pGL3-I-del, construct in which
the sequence from bp 1864 to 2113 has been removed from the BRCA1 gene.
All mutant promoters were active in EJ-p53 cells grown in the presence
of tet. (Right) Relative luciferase activities obtained following
transient transfection of those constructs in the presence or absence
of tet. Transfection and activity measurements were done as indicated
for panel A. Mutant constructs containing the BRCA1 sequence from bp
1893 to 2052 were repressed by p53. (C) Dissection of the bp 1893 to
2052 region of the BRCA1 gene. A 50-bp region including a BRCA1
TATA-like sequence (TTTAAA-containing sequence) under the control of
the SV40 promoter causes a 50% decrease in luciferase activity
following p53 induction, while its mutation reverses BRCA1 repression
by p53.
|
|
To localize the region(s) of the BRCA1 gene mediating the observed
negative regulation by p53, a number of deletion constructs
spanning
the promoter (Fig.
5B) were inserted upstream of the
luciferase
reporter of pGL3-basic vector (Promega). The constructs
were
transiently transfected into the EJ-p53 cells in the presence
of tet
(p53 repressed), and their transactivation activities relative
to that
of the pGL3-basic vector (whose activity was arbitrarily
defined as 1)
were calculated. All the constructs were expressed,
though they showed
different activities. The strongest activity
was detected from
pGL3-III, while the weakest was from pGL3-I
(Fig.
5A and B). In order
to study the effect of p53 induction
on the activities of BRCA1
deletion mutants, the reporter constructs
were transiently transfected
into EJ-p53 cells grown in the presence
or absence of tet, and their
luciferase activities were compared.
Those reporters containing a
region of 160 bp spanning from bp
1893 to 2052, such as pGL3-III and
pGL3-V (Fig.
5B, left) were
inhibited up to 60% following p53
induction (Fig.
5B, right).
In contrast, constructs containing
deletions of bp 1893 to 2052
within the BRCA1 promoter, such as
pGL3-II, pGL3-IV, and pGL3-I-del
(Fig.
5B, left), failed to show a
decrease in luciferase activity
upon p53 induction (Fig.
5B, right). A
DNA sequence homology search
of this 160-bp region with the databases
(
22) revealed several
known transcription factor elements
including AP1, ERE, NF-
B,
and a TATA-like sequence (TTTAAA),
but no consensus p53 binding
site. To further analyze the 160-bp
region of the
BRCA1 promoter,
several constructs, each containing a
putative transcription factor
binding site, were made upstream of the
SV40 luciferase reporter
gene of pGL3-CV. The luciferase gene under the
control of the
50-bp construct containing the TATA-like sequence showed
more
than 50% reduction in activity following p53 induction, while
a
mutated form of this sequence (TTTAAA to TGCTCG)
failed to show
major inhibition (Fig.
5C). The activities of
constructs containing
the region including ERE and AP1 (Fig.
5C) and
the NF-
B domain
(data not shown) remained almost unchanged when tet
was removed
from the cell media. These data demonstrate that p53 mainly
affects
BRCA1 transcription and show that BRCA1 repression requires a
160-bp region within the BRCA1 gene, which contains a TTTAAA
sequence
that allows p53 to repress transcription by a
still-unknown
mechanism.
| |
DISCUSSION |
Eukaryotic cells ensure genetic integrity after sustaining DNA
damage or defects in DNA metabolism by regulating the progression through the cell cycle. Under these circumstances, the cellular level
of p53 protein increases, causing either cell cycle arrest or
apoptosis. In the present study, we show that, as part of the cellular
response to sustained DNA damage and/or p53 induction, (i) BRCA1 is
first converted to a slower-migrating peptide, which probably
corresponds to a phosphorylated form of the protein, then (ii) BRCA1
mRNA and protein levels are down-regulated in a p53-dependent manner,
and (iii) this decrease is mainly due to changes in the transcriptional
rate of the BRCA1 gene. The results indicate that BRCA1 is negatively
regulated by p53 and suggest the existence of an intracellular
p53/BRCA1 pathway in responding to stress conditions.
Following exposure of cells to DNA damage, such as gamma irradiation,
we observed that the BRCA1 protein was first converted to a
slower-migrating form, which likely reflects phosphorylation of the
protein, and then the protein levels were significantly reduced in a
p53-dependent manner. Several studies have already reported the
appearance of a BRCA1 doublet in the first few hours following DNA
damage corresponding to the presence of both BRCA1 p220 and a
phosphorylated form (47, 56). It is noteworthy that we have
not observed this higher-molecular-weight form of BRCA1 or the
disappearance of BRCA1 expression in mutant p53-carrying cells, such as
T47D, EJ, and PC3 cells, only in cells containing wild-type p53.
More-recent reports have indicated that BRCA1 can be phosphorylated on
a serine residue (amino acid 1497) by a cyclin-dependent kinase, Cdk2
(44). Furthermore, ATM seems to be required for phosphorylation of BRCA1 in response to radiation ionization
(10). Therefore, accumulating evidence suggests that BRCA1
may be a substrate of one or more kinases activated in response to DNA damage.
p53 is known for its ability to act as a transcriptional transactivator
by specifically binding to p53 response elements and activating the
expression of a number of genes (reviewed in references 1,
28, and 29). However, the p53 protein also
has a less-well-characterized activity as a negative regulator of
transcription (13, 14, 36, 50, 58). In the present study, we
demonstrate that wt p53 induction was followed by a significant
reduction of BRCA1 mRNA and protein levels in cells undergoing either
apoptosis (Vm10 cells), reversible G1 arrest (VhD cells),
or irreversible G1 arrest (EJ-p53). Endogenous BRCA1 gene
expression is also decreased following physiological induction of wt
p53 by DNA damage. We have also demonstrated, through nuclear run-on
experiments, that p53 induction alters the transcription rate of the
BRCA1 gene. In addition, constructs containing a 160-bp region within
the BRCA1 gene spanning from bp 1893 to 2052, and in particular those
containing a TTTAAA sequence within it, showed a reduction
in transcriptional activity, as seen in luciferase reporter assays. Our
data also suggest that BRCA1 disappearance at the protein level can be
explained partially by BRCA1 protein destabilization. Further analyses
need to be done in order to determine if the acidic-cysteine proteases
known to be involved in BRCA1 protein metabolism are activated by p53. Altogether, these results demonstrate that BRCA1 expression is modulated by p53 and place BRCA1 among the growth control and/or DNA
repair-related genes under the regulatory control of wt p53.
Previous reports have indicated that BRCA1 mRNA and protein levels
change as the cell cycle progresses, with decreased levels observed in
G1 phase (43, 56). Here, we have shown that
down-regulation of BRCA1 at the mRNA and protein levels preceded
p53-induced cell cycle arrest and apoptosis, implying that BRCA1
modulation is p53 dependent and not a consequence of cell cycle
inhibition. It remains to be elucidated whether BRCA1 down-regulation
is a requirement for p53-induced cell cycle arrest and apoptosis to occur or if the two phenomena are independent.
There is accumulating evidence suggesting that BRCA1 plays a role in
DNA repair pathways (16, 35; reviewed in reference 65). It is then difficult to understand why BRCA1
disappears shortly after the DNA damage has been produced, when
apparently it is most needed. In that respect, the BRCA1 gene contains
two BRCT domains that could be responsible for the transcriptional activation function of the BRCA1 C-terminal region (33); M. S. Chapman and I. M. Verma, Letter, Nature
382:678-679, 1996. It could be, as for c-fos and
other transcription factors (4), that once it is activated
BRCA1 targets other genes in the DNA repair chain and then disappears.
Thus, one possible scenario is that BRCA1, once phosphorylated, may act
synergistically with p53 to activate the p53 pathways of cell cycle
arrest and DNA damage response, and then may be repressed and/or
degraded in a p53-dependent manner when it is no longer needed. In
contrast, in the absence of p53, when DNA damage occurs, we observe
that BRCA1 is maintained inside the cells for longer periods of time and postulate that the accumulation of unrepaired damage may later trigger the cells to arrest or apoptosis in a BRCA1-dependent, p53-independent pathway. In this regard, the absence of BRCA1 is also
thought to trigger the action of p53 and its target genes in
BRCA/ mice (18, 64). In the present study,
we show that BRCA1 phosphorylation and subsequent down-regulation are
part of a coordinated response to p53 induction under physiological
conditions. While the exact relationship between both tumor suppressor
genes remains to be further elucidated, p53 mutations are frequently
associated with familial BRCA1-associated tumors (12,
40; T. Crook, S. Crossland, M. R. Compton, P. Osin, and
B. A. Gusterson, Letter, Lancet 350:638-639, 1997). An
increased incidence of mammary tumors was observed in the
BRCA1+/, p53/ mice (11).
Moreover, the loss of p53 accelerated the formation of mammary tumors
in female mice with mammary epithelium-specific inactivation of BRCA1
(64). Altogether, the data suggest that the loss of BRCA1
and p53 genes may be integral to the progression of tumorigenesis in
breast cancer.
| |
ACKNOWLEDGMENTS |
We thank A. M. Borras, J. R. Garreau, J. Licht, J. Manfredi, C. L. Reimer, and H. Zhang for helpful comments and discussion.
This work was supported by NIH grants CA78356, P50CA68425, P01CA80058,
and CA79892.
| |
ADDENDUM IN PROOF |
W. S. El-Deiry's group has obtained results similar to
those presented in this paper, and we thank them for communicating their data before publication (J. Biol. Chem., in press).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medicine, Harvard Medical School and Beth Israel Deaconess Medical
Center, Harvard Institutes of Medicine, Suite 921, 77 Ave. Louis
Pasteur, Boston, MA 02115. Phone: (617) 667-8563. Fax: (617) 667-0980. E-mail: slee2{at}caregroup.harvard.edu.
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Molecular and Cellular Biology, October 2000, p. 7450-7459, Vol. 20, No. 20
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
