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Molecular and Cellular Biology, July 2000, p. 4849-4858, Vol. 20, No. 13
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
p53 Recruitment of CREB Binding Protein Mediated
through Phosphorylated CREB: a Novel Pathway of Tumor Suppressor
Regulation
Holli A.
Giebler,
Isabelle
Lemasson, and
Jennifer K.
Nyborg*
Department of Biochemistry and Molecular
Biology, Colorado State University, Fort Collins, Colorado
80523-1870
Received 29 December 1999/Returned for modification 16 February
2000/Accepted 23 March 2000
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ABSTRACT |
CREB binding protein (CBP) is a 270-kDa nuclear protein required
for activated transcription of a large number of cellular genes.
Although CBP was originally discovered through its interaction with
phosphorylated CREB (pCREB), it is utilized by a multitude of cellular
transcription factors and viral oncoproteins. Both CREB and the tumor
suppressor p53 have been shown to directly interact with the KIX domain
of CBP. Although coactivator competition is an emerging theme in
transcriptional regulation, we have made the fortuitous observation
that protein kinase A-phosphorylated CREB strongly enhances p53
association with KIX. Phosphorylated CREB also facilitates interaction
of a p53 mutant, defective for KIX binding, indicating that CREB
functions in a novel way to bridge p53 and the coactivator. This is
accomplished through direct interaction between the bZIP domain of CREB
and the amino terminus of p53; a protein-protein interaction that is
also detected in vivo. Consistent with our biochemical observations, we
show that stimulation of the intracellular cyclic AMP (cAMP) pathway,
which leads to CREB phosphorylation, strongly enhances both the
transcriptional activation and apoptotic properties of p53. We propose
that phosphorylated CREB mediates recruitment of CBP to p53-responsive
promoters through direct interaction with p53. These observations
provide evidence for a novel pathway that integrates cAMP signaling and
p53 transcriptional activity.
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INTRODUCTION |
CREB binding protein (CBP) is a
large pleiotropic cellular coactivator protein critical to the
execution of virtually all known cellular programs, including cell
growth, differentiation, the integration of both signal-dependent and
-independent cellular responses, and apoptosis. CBP and its sister
protein p300 are highly conserved in multicellular organisms from
Caenorhabditis elegans to mammals and have been shown to
have profound effects on somatic differentiation during early
embryogenesis (2, 20, 33, 38). CBP interacts with a
multitude of structurally unrelated cellular transcription factors,
promoting selective gene activation by providing communication between
promoter-bound transcription factors and components of the basal
transcription apparatus (34). Following promoter
localization of CBP, the coactivator is also believed to directly
acetylate nucleosomes, leading to transcriptional activation through
localized chromatin remodeling. These acetylation events are carried
out through both intrinsic and associated (P/CAF) histone
acetyltransferase activities (7, 28).
CBP was originally discovered, and thus named, through its interaction
with the kinase-inducible activation domain (KID) of the cellular
transcription factor CREB (4, 11, 23). Protein kinase A
(PKA) phosphorylation of a critical serine residue on CREB (amino acid
[aa] 133) is required for complex formation between these two
proteins (29). A small subdomain of CBP (aa 586 to 679),
called the KIX domain, participates in protein-protein interaction with
pCREB (31). KIX is composed of three interacting 
helices that come together to form a hydrophobic core. A shallow groove on the
surface of the KIX structure provides the site for molecular interaction with pCREB.
Although pCREB complexed with the KIX domain of CBP has been well
characterized, KIX has also been shown to interact with several other
proteins, including the tumor suppressor p53 (36). p53 is a
transcription factor that induces cell cycle arrest or apoptosis in
response to a variety of cellular stress signals, thereby preventing
the transmission of genetic mutations (reviewed in reference
22). Mutations within the coding sequence of the p53
gene, leading to loss of p53 activity, have been identified in 60% of
the human malignancies examined (17, 25). This statistic underscores the significance of p53 in genome surveillance and suppression of malignant transformation. The transcriptional activity of p53, which is tightly linked to its tumor suppressor function, appears to depend upon efficient recruitment of CBP to p53 target promoters. Consistent with this observation, recent studies have shown
that the activation domain of p53 participates in CBP recruitment (16, 36). Together, these findings indicate that CBP plays a
critical role in supporting p53-dependent transcription function.
The recent study showing p53 binding to KIX led us to ask whether both
pCREB and p53 bind to KIX in a mutually exclusive manner, possibly
leading to coactivator competition within the cell. From this line of
investigation, we made the surprising observation that pCREB strongly
facilitates p53 association with KIX. We demonstrate that
phosphorylated CREB, but not unphosphorylated CREB, mediates p53
association with KIX, and that this is accomplished through protein-protein interaction between the basic leucine zipper (bZIP) domain of CREB and the amino terminus of p53. The significance of this
interaction is supported by studies showing that p53 and CREB interact
in vivo and that p53 function is enhanced by forskolin, a stimulator of
the PKA signal transduction pathway. These data support a model where
phosphorylated CREB bridges the interaction between promoter-bound p53
and CBP, furnishing an alternate mechanism of coactivator recruitment
to p53-responsive genes. Finally, the evidence supports a unique form
of transcription factor organization, leading to multilayered
regulation of gene expression, and underscores the importance of CBP in
mediating convergent signaling pathways.
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MATERIALS AND METHODS |
Cloning, expression and purification of recombinant
proteins.
Glutathione S-transferase (GST)-KIX (CBP aa
588 to 683), His6-p53, His6-p53 (L22Q-W23S)
(36), and KID (CREB aa 100 to 160) (27) were
expressed and purified as previously described.
pGST-CREB-His6 expression plasmid was provided by C.-Z.
Giam and was expressed and purified as described (18).
GST-p53 was made by PCR amplification of the p53 gene, followed by
insertion into pDEST 15 for expression in Escherichia coli
and pDEST 10 for use in the Bac-To-Bac baculovirus expression system
(Life Technologies). Proteins were purified to near homogeneity,
dialyzed against TM 0.1 M KCl buffer (50 mM Tris-HCl [pH 7.9], 100 mM
KCl, 12.5 mM MgCl2, 1 mM EDTA [pH 8.0], 20% glycerol,
0.025% [vol/vol] Tween 20, 1 mM dithiothreitol), aliquoted, and
stored at 
70°C. p53 proteins were dialyzed against 20 mM Tris-HCl
[pH 8.0]-100 mM KCl-0.5 mM EDTA-20% glycerol. PKA phosphorylation
of CREB and KID was performed as previously described (15).
GST pull-down assays.
All GST pull-down experiments were
performed using 12.5 µl of glutathione-agarose beads equilibrated in
0.5× Superdex buffer (1× Superdex buffer is 25 mM HEPES [pH 7.9],
12.5 mM MgCl2, 10 µM ZnSO4, 150 mM KCl, 20%
[vol/vol] glycerol, 0.1% Nonidet P-40, and 1 mM EDTA). The purified
GST fusion protein was incubated with the beads for 1 to 2 h at
4°C and then washed with 0.5× Superdex buffer. The second protein(s)
was then added to the washed beads and incubated for 1 to 2 h (or
overnight) at 4°C. The beads were washed as before, and bound
proteins were eluted with sodium dodecyl sulfate (SDS) sample dyes.
Bound proteins were separated by electrophoresis on a 10% or 12% SDS
gel or a 10% Tris-Tricine gel, transferred to nitrocellulose, and
probed with the appropriate antibody. The following antibodies were
used in this study: anti-p53 (DO-1 [epitope corresponding to aa 11 to
25]; Santa Cruz Biotechnology), anti-p53 (Ab-1 [epitope corresponding
to aa 371 to 380]; Calbiochem), anti-CREB (C-21 [epitope
corresponding to the carboxy terminus of human CREB-1]; Santa Cruz
Biotechnology), anti-phosphoserine 133-CREB (New England Biolabs), and
anti-His (H-15; Santa Cruz Biotechnology).
Cell culture, transient cotransfection assays, and expression
plasmids.
Jurkat T cells and Molt 4 T cells were cultured in
Iscove's modified Dulbecco's medium supplemented with 10% fetal
bovine serum (FBS), 2 mM L-glutamine, and
penicillin-streptomycin. The H24 p53-3 cells were grown in Dulbecco's
modified Eagle's medium supplemented with 10% FBS, tetracycline (2 µg/ml), puromycin (1 µg/ml), and geneticin (250 µg/ml). The MCF7
breast cancer cells were cultured in Eagle's minimum essential medium
supplemented with 2 mM L-glutamine,
penicillin-streptomycin, Earle's BBS adjusted to contain 1.5 g of
sodium bicarbonate per liter, a 0.1 mM concentration of nonessential
amino acids, 1.0 mM sodium pyruvate, 10% FBS, and 0.01 mg of bovine
insulin per ml. For transient cotransfection assays (36),
cells were grown to a density of 106 cells/ml and
transfected with Lipofectamine (Life Technologies, Inc.) and a constant
amount of DNA for 5 h. The cells were allowed to recover for
24 h before harvest, in the absence or presence of 20 µM
forskolin. Cells were lysed, and luciferase activity was measured using
the Dual-Luciferase reporter assay system with a Turner Designs model
TD 20-e luminometer. Luciferase activity was normalized to pRL-TK
vector (Promega), which encodes the Renilla luciferase from
HSV-TK promoter, as an internal control. Expression plasmids for p53
(pC53-SN3 [6]), RSV-PKA, or Gal4-p53 fusion proteins
carrying p53 aa 1 to 393 (pGalp53) or aa 1 to 52 (pGalp53N) (12) have been previously described. The luciferase reporter plasmids pG13-Luc (21), pGalTK-Luc (12), and
viral CRE-Luc (15) have also been described. The Bax-Luc
reporter plasmid was prepared by cloning the Bax promoter (340 to
+31) upstream of the luciferase gene.
Western blots.
MCF7 cells were grown to 70% confluency,
medium was removed, and fresh medium was added to the cells in the
absence or presence of 20 µM forskolin, and the cells were incubated
for the indicated amount of time. Cells were lysed and resuspended in
SDS sample dyes. Proteins were separated on a 10% Tris-Tricine
SDS-polyacrylamide gel electrophoresis and analyzed by Western blot analysis.
Northern blots.
MCF7 cells were grown to ~70% confluency,
the medium was removed and fresh medium was added to the cells in the
absence or presence of 20 µM forskolin and incubated for 45 min. The
cells were harvested in a solution containing 4 M guanidinium
thiocyanate, 0.5% sarcosyl, and 25 mM sodium citrate, pH 7.0, and
total RNA was isolated using acidic phenol extraction followed by
isopropanol precipitation and resuspension in FORMAzol (Molecular
Research Center, Inc.). Purified total RNA (15 µg) was separated by
electrophoresis on a 1% agarose-formaldehyde-MOPS (morpholinepropane
sulfonic acid) gel, transferred to Genescreen (DuPont-NEN) membrane,
and cross-linked for 3 min with UV radiation at a wavelength of 320 nm.
Membranes were hybridized at 43°C with 32P-labeled cDNA
probes complimentary to either the p21 or GAPDH mRNAs. The membrane was
washed several times, dried, and analyzed by Phosphorimager analysis.
Coimmunoprecipitation (co-IP) assays.
Molt 4 T-cell lysates
were prepared in RIPA buffer (50 mM Tris-HCl [pH 8.0], 1% Triton
X-100, 100 mM NaCl, 1 mM MgCl2, 2 mM benzamidine, 2 µg of
leupeptin per ml, and 1 mM phenylmethylsulfonyl fluoride).
Antibody-bound beads (20 µl) (Ab-1 [epitope corresponding to aa 371 to 380] [Calbiochem] or DO-1 [epitope corresponding to aa 11 to
25] [Santa Cruz Biotechnology]) were washed in RIPA buffer. Cell
lysates (500 µg) were added to each antibody column, incubated
overnight, and washed several times in RIPA buffer. The bound proteins
were analyzed on an SDS-10% polyacrylamide gel, and detected by
Western blotting using anti-CREB-1 antibody (C-21 [epitope
corresponding to aa 295 to 321]; Santa Cruz Biotechnology) and
anti-p53 (DO-1; Santa Cruz Biotechnology).
Apoptotic analysis.
Molt 4 T-cells (5 × 105 cells) and H24 p53-3 cells (reference
10) were treated with the indicated concentrations
of forskolin (or dimethyl sulfoxide carrier) for 24 h. In the
p53-inducible cell line H24 p53-3, tetracycline was removed at the time
of forskolin addition. Cells were harvested and treated with YO-PRO-1
(from Vybrant apoptosis assay kit no. 4; Molecular Probes). Cells were deposited on microslides coated with poly-L-lysine
(Poly-Prep slides; Sigma), and the fluorescent apoptotic cells were
analyzed and photographed using a fluorescence microscope.
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RESULTS |
pCREB enhances p53 association with the KIX domain of CBP.
In
a recent structural study characterizing the
phosphorylated-kinase-inducible domain of CREB bound to the hydrophobic
groove on the surface of KIX, the authors noted key sequence and
structural similarities between phosphorylated KID (pKID) and the
activation domain of p53 (31). This led to the prediction
that the hydrophobic groove on the surface of KIX may also serve as the
binding site for p53. To test this hypothesis, we performed a GST
pull-down competition experiment to determine whether titration of
pCREB can displace p53 bound to KIX. Purified GST-KIX (aa 588 to 683) was bound to glutathione-agarose beads and incubated with recombinant, purified p53. Increasing amounts of PKA-phosphorylated CREB were added
into the binding reaction mixtures, and the amount of p53 remaining
bound to KIX was determined by Western blot analysis (Fig.
1A). Surprisingly, the addition of pCREB
did not compete with p53 for binding to KIX but produced a dramatic
increase in the amount of p53 associated with the complex (compare
lanes 4 to 7). As expected, neither p53 nor pCREB bound to GST beads
alone (Fig. 1A, lanes 2 and 3).
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FIG. 1.
(A) CREB enhances p53 binding to the KIX domain of CBP.
Purified p53 (5 pmol) was incubated with either GST alone (1 pmol)
(lanes 2 and 3) or GST-KIX (aa 588 to 683) (1 pmol) (lanes 4 to 7) in
the absence () and presence (+) of the indicated amount of purified,
PKA-phosphorylated CREB. Bound p53 protein was detected by Western blot
analysis. Onput protein (6%) is shown in lane 1 and protein standards
(in kilodaltons) are indicated at left. (B) pCREB, but not
unphosphorylated CREB, enhances p53 binding to the KIX domain of CBP.
Purified p53 (5 pmol) was incubated with GST-KIX (1 pmol) in the
absence or presence of the indicated amounts of either purified pCREB
(lanes 3 to 5) or purified, mock-phosphorylated CREB (lanes 6 to 8).
p53 (upper panel) was detected by Western blot analysis, and bound
protein is indicated. The blot was reprobed using an anti-CREB
antibody, and bound protein is indicated in the lower panel. Onput
protein (2%) is shown in lane 1 and protein standards (in kilodaltons)
are indicated at left. (C) p53 does not enhance the binding of CREB to
the KIX domain of CBP. Purified, phosphorylated or mock-phosphorylated
CREB (10 pmol) was incubated with GST-KIX (10 pmol) in the absence or
presence of the indicated amount of purified p53 (lanes 3 to 5 and 7 to
9). CREB (upper panel) was detected by Western blot analysis. The blot
was reprobed using an anti-p53 antibody, and bound protein is indicated
in the lower panel. Onput protein (2%) is shown in lane 1, and protein
standards (in kilodaltons) are indicated at left.
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We were next interested in determining whether the increase in p53
association with KIX was specific to pCREB or if unphosphorylated
CREB
could also promote the interaction. To test this hypothesis,
we again
compared the binding of p53 to KIX following the addition
of increasing
amounts of either unphosphorylated or phosphorylated
CREB. As shown in
the GST pull-down assay in Fig.
1B (upper panel),
we observed
enhancement of p53 binding to KIX only in the presence
of pCREB
(compare lanes 2 to 5). In fact, increasing amounts of
unphosphorylated
CREB appeared to reduce the p53-KIX interaction
in a dose-dependent
manner (compare lane 2 with lanes 6 to 8).
Interestingly, we observed
that the enhancement of p53 association
with KIX correlated precisely
with pCREB binding to KIX, suggesting
that both pCREB and p53 are
simultaneously in complex with this
region of CBP (Fig.
1B, compare
lanes 3 to 5 of the upper and
lower panels). Further, these data
strongly support a role for
a direct pCREB-KIX molecular interaction in
ternary complex formation.
As expected, we did not detect the binding
of unphosphorylated
CREB to the KIX domain (Fig.
1B, lower panel, lanes
6 to
8).
To better characterize the ternary complex containing pCREB, p53, and
KIX, we performed the reciprocal experiment and tested
whether p53
could also enhance pCREB binding to KIX. We performed
a GST pull-down
assay in which p53 was titrated into binding reaction
mixtures
containing GST-KIX and a constant amount of either phosphorylated
or
unphosphorylated CREB. As shown in Fig.
1C, p53 had only a
modest
effect on pCREB binding to KIX and no detectable effect
on CREB binding
to KIX (lanes 2 to 9). These data suggest that
pCREB plays the primary
role in facilitating formation of the
ternary complex. This conclusion
is further supported by the observation
that significantly more
KIX-associated p53 was detected in the
presence of pCREB than in the
presence of unphosphorylated CREB
(Fig.
1C, lower panel, compare lanes
3 to 5 with lanes 7 to
9).
pCREB contacts KIX in the ternary complex.
The solution
structure of the pCREB-KIX complex reveals intimate molecular contacts
between the hydrophobic groove of KIX and the pKID domain of CREB
(31). Although we do not know where p53 binds on the surface
of KIX, it seems unlikely that the hydrophobic groove could accommodate
both pCREB and p53 simultaneously. The strong dependence on CREB
phosphorylation in ternary complex formation suggests that pCREB
directly contacts the hydrophobic groove, as previously described
(31). To determine whether, in the ternary complex, p53 also
directly contacts KIX, we utilized an activation domain mutant of p53
(L22Q-W23S) that we have previously shown to be defective for KIX
binding (36). We reasoned that if p53 makes direct contacts
with KIX in the ternary complex, then the mutant p53 should also be
defective for ternary complex formation. On the other hand, if pCREB
alters or abolishes the p53-KIX interaction, then we may observe
enhanced binding of both wild-type and mutant forms of p53. To sort out
these questions, we compared the binding of the wild-type and mutant
forms of p53 to GST-KIX in the presence of pCREB. We found that both
forms of p53 bound well in the ternary complex, with the binding of
each molecule dependent upon pCREB (Fig. 2A, lanes 3 and
5). These data indicate that aa 22 and 23 of the p53 activation domain are not involved in ternary complex formation and support the idea that pCREB alters or abolishes the
p53-KIX interaction.
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FIG. 2.
(A) A p53 mutant, defective for KIX binding, binds KIX
in the presence of pCREB. Purified wild-type (wt) (10 pmol) (lanes 2 and 3) or mutant (mut) (L22Q-W23S) (10 pmol) (lanes 4 and 5) p53 was
incubated with GST-KIX (2 pmol) in the absence or presence of 30 pmol
of purified, phosphorylated CREB. p53 and CREB were detected
simultaneously by Western blot analysis using an anti-His-anti-CREB
antibody mixture. Onput wt p53 (2%) is shown in lane 1, and protein
standards (in kilodaltons) are indicated at left. At the exposure
presented, p53 binding to KIX was not detected. (B) The
PKA-phosphorylated kinase-inducible domain of CREB does not support
enhanced binding of p53 to KIX. Purified p53 (10 pmol) was incubated
with GST-KIX (10 pmol) in the absence or presence of 30 pmol of
phosphorylated full-length CREB (lane 2) or pKID domain of CREB (lane
3). p53 was detected by Western blot analysis. Protein standards (in
kilodaltons) are indicated at left.
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Two possible scenarios are consistent with the data presented in Fig.
2A. In the presence of pCREB, p53 forms different contacts
with KIX, or
alternatively, p53 binding to KIX is abolished. The
second possibility
would therefore require a direct CREB-p53 interaction
as a means to
incorporate p53 into the ternary complex. To test
this possibility, we
utilized a highly truncated form of CREB
that encompassed only the
Ser-133 phosphorylated-kinase-inducible
domain (CREB aa 115 to 148).
Although this region of CREB lacks
the bZIP and the Q domains, it is
competent for interaction with
KIX (
29,
31). To determine
whether pKID alone can enhance
p53 association with KIX, we compared
pKID in parallel with full-length
pCREB in a GST-KIX pull-down assay
(Fig.
2B). Interestingly, the
pKID domain had no effect on p53
association with KIX (Fig.
2B,
lane 3). Both pCREB and pKID were fully
competent for KIX binding,
as assayed in a GST-KIX pull-down reaction
(data not shown). These
data indicate that a region of CREB, outside of
the KIX-interacting
kinase-inducible domain, is required for efficient
formation of
the ternary complex. Furthermore, they are consistent with
the
idea that CREB and p53 interact
directly.
Characterization of the CREB-p53 interaction in vitro and in
vivo.
Based on the data presented above, we began to formulate a
model where the p53-pCREB-KIX ternary complex is formed through direct
pCREB interaction with the hydrophobic groove of KIX, with p53
incorporated into the coactivator complex via protein-protein interaction with CREB. To directly test for a p53-CREB interaction, we
examined the binding of p53 to GST-CREB, in the absence of KIX. As
shown in Fig. 3A, both wild-type and
mutant p53 (L22Q-W23S) interacted equally well with GST-CREB (lanes 5 and 6). To confirm the p53-CREB interaction, we performed the
reciprocal GST pull-down assay. As shown in Fig. 3B, both
phosphorylated and unphosphorylated forms of full-length CREB bound
equally well to GST-p53 in the absence of KIX (lanes 2 and 4). Taken
together, these results indicate that p53 interacts directly with CREB,
in a binding reaction that is independent of KIX. Together, these data
provide direct evidence for a novel interaction between CREB and p53
and support the hypothesis that pCREB enhancement of p53 binding to KIX
is mediated through a direct p53-CREB protein-protein interaction. Finally, we were interested in testing whether posttranslational modifications of p53 might affect interaction with CREB. Figure 3C
shows that GST-p53 derived from baculovirus-infected Sf9 cells interacted with CREB in a manner indistinguishable from that observed with p53 derived from E. coli (compare Fig. 3C, lane 3, with
Fig. 3B, lane 2). These data suggest that Sf9 cells do not introduce modifications in p53 that affect interaction with CREB. We have also
shown that GST-CREB interacts with non-GST-tagged forms of p53, derived
from both E. coli (Fig. 3A) and baculovirus-infected Sf9 cells (data not shown).
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FIG. 3.
(A) Wild-type (wt) and mutant (mut) (L22Q-W23S) p53
directly interact with CREB in the absence of KIX. Purified wt or
mutant p53 protein (10 pmol each) was incubated with either GST alone
(10 pmol) (lanes 3 and 4), or GST-CREB-His6 (10 pmol)
(lanes 5 and 6). Bound p53 proteins were detected by Western blot
analysis. Onput protein (10%) is shown in lanes 1 and 2, and protein
standards (in kilodaltons) are shown at left. (B) PKA-phosphorylated or
mock-phosphorylated CREB (25 pmol) was incubated with either GST alone
(100 pmol) (lanes 1 and 3) or GST-p53 (100 pmol) (lanes 2 and 4). Bound
CREB was detected by Western blot analysis. Output proteins (10%)
(lanes 5 and 6) and protein standards (in kilodaltons) are indicated.
(C) CREB (5 pmol) was incubated with either GST alone (10 pmol) (lane
2) or GST-p53 produced and purified from baculovirus-infected Sf9 cells
(10 pmol) (lane 3). Bound CREB was detected by Western blot analysis.
Onput protein (10%) (lane 1) and protein standards (in kilodaltons)
are indicated.
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To determine which region of CREB interacts with p53, we tested a
series of CREB deletion mutants in the GST pull-down assay
using
GST-p53. Most of the CREB deletions were centered in the
region of KID
and extended into both the Q1 and Q2 domains (Fig.
4A). Surprisingly, all the CREB deletion
mutants tested were competent
for binding to GST-p53 (Fig.
4B, lanes 1 to 6). Since all of the
mutants possessed the bZIP domain (aa 254 to 327) (and a portion
of Q1 and Q2), we directly tested whether bZIP
alone was competent
for p53 binding. Figure
4C shows that both
full-length CREB and
bZIP bound GST-p53 with comparable relative
affinities (lanes
2, 3, 5, and 6).
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FIG. 4.
(A) Schematic of the CREB deletion mutants. (B) CREB
deletion mutants are competent for p53 binding. The indicated CREB
deletion mutants (10 pmol) were incubated with GST-p53 (25 pmol) (lanes
1 to 6). Bound CREB proteins were detected by Western blot analysis.
Protein standards (in kilodaltons) are indicated. (C) The bZIP domain
is sufficient for interaction with p53. The indicated amounts of either
full-length or bZIP (aa 254 to 327) CREB were incubated with GST alone
(100 pmol) (lanes 1 and 4) or GST-p53 (100 pmol) (lanes 2, 3, 5, and
6). Bound CREB was detected by Western blot analysis. Onput proteins (5 pmol of CREB, 10 pmol of bZIP) (lanes 7 and 8), and molecular mass
standards (in kilodaltons) are indicated. (D) Anti-p53
immunoprecipitates ATF/CREB proteins from a T-cell lysate. The upper
panel shows a CREB Western blot of the proteins bound to p53
immobilized using either the Ab-1 or DO-1 anti-p53 antibodies (lanes 2 and 3). Purified, recombinant CREB was electrophoresed as a control
(lane 1). The lower panel shows a Western blot of p53 bound to the
immobilized anti-p53 antibodies (lanes 2 and 3).
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Although these studies establish an interaction between CREB and p53 in
vitro, we were interested in determining whether this
interaction could
also be detected in vivo. To investigate this
possibility, we performed
a co-IP assay in which a carboxy terminus-reactive
p53 antibody
(epitope corresponding to aa 371 to 380) was immobilized
on a resin. A
lysate prepared from the wild-type p53-expressing
T-cell line, Molt4,
was then passed over the column, the column
was washed, and the bound
proteins were analyzed by Western blot
analysis using an anti-CREB
antibody. As shown in Fig.
4D (upper
panel), we detected several
anti-CREB immunoreactive polypeptides,
ranging in molecular mass from
about 35 to 45 kDa. The band with
the highest molecular mass comigrated
with recombinant CREB, indicating
that it likely represents endogenous
CREB in the Molt4 lysate
(Fig.
4D, compare lanes 1 and 3). The other
polypeptides are likely
cross-reactive ATF/CREB family members (CREM
and ATF-1). In a
parallel reaction, we also performed the co-IP assay
using an
anti-p53 antibody reactive against the amino terminus of p53
immobilized
on the resin (epitope corresponding to aa 11 to 25) and
probed
for bound polypeptides using the anti-CREB antibody.
Interestingly,
we did not detect the binding of any ATF/CREB proteins
when the
amino-terminal p53 antibody was used in the co-IP, suggesting
that this antibody masks critical p53 amino acids that may be
required
for interaction with CREB (Fig.
4D, upper panel, lane
2). p53 bound
equally well to both the amino-terminal and carboxy-terminal
antibodies
(Fig.
4D, lower panel, lanes 2 and 3). These data support
the in vitro
data and provide evidence for the binding of multiple
ATF/CREB proteins
to p53 in vivo. Furthermore, the results suggest
that the amino
terminus of p53 participates in the protein-protein
interaction with
CREB.
Activation of the PKA pathway stimulates p53 function.
Our
biochemical characterization of the ternary complex led us to address
the question of whether the binding of p53 to pCREB and the formation
of a complex with CBP might facilitate the biological effects of p53 in
the cell. To first address this question, we were interested in testing
whether forskolin, a stimulator of adenylate cyclase and the cyclic AMP
(cAMP) pathway, might induce apoptosis. We treated p53-positive Molt4 T
cells with increasing concentrations of forskolin, and monitored the
cells undergoing apoptosis. Figure 5A
shows that forskolin treatment produced a significant increase in the
number of apoptotic cells in a concentration-dependent fashion.
Treatment of p53-negative Jurkat T cells had no effect on cell death
(data not shown). However, since these experiments did not address
whether the observed apoptotic effects were directly mediated through
endogenous p53, we also tested whether forskolin induced apoptosis in
the p53-inducible (tet-regulated) cell line, H24 p53-3
(10). Figure 5B shows that, upon induction of p53, forskolin
treatment produced a significant increase in the number of cells
undergoing apoptosis. Although the effect was not as dramatic as that
observed in the Molt4 T cells, Western blot analysis indicated that p53
expression was significantly lower in the H24 p53-3 cell line than in
Molt4 cells (Fig. 5C).
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FIG. 5.
Induction of apoptosis by forskolin. (A) Molt 4 cells
were treated with the indicated concentrations of forskolin for 24 h. (B) H24 p53-3 cells (10) were removed from
tetracycline-containing medium and immediately treated with forskolin
for 24 h. Apoptotic cells (upper panels) were detected under
fluorescent microscopy using YO-PRO-1. Lower panels correspond to
bright-field microscopy of the cells presented in the upper panel. (C)
Western blot analysis of H24 p53-3 extracts derived from cells grown in
the presence (uninduced) (+) and absence (induced) () of
tetracycline. Extracts from Molt4 cells were run in an adjacent lane
for comparison. p53 protein was detected by Western blot analysis
(DO-1).
|
|
To more directly address the role of forskolin on p53 transcription
function, we performed transient-transfection assays.
Jurkat T cells
were transiently transfected with a reporter plasmid
carrying 13 copies
of a p53-responsive promoter driving expression
of the luciferase gene
(pG13-Luc). As expected, transfection of
a p53 expression plasmid
dramatically stimulated luciferase expression
from the p53-responsive
reporter plasmid (Fig.
6A, lane 4).
Treatment
of the cells with 20 µM forskolin further increased
p53-dependent
transcriptional activity, resulting in an additional
twofold stimulation.
The effect of forskolin was only observed in the
presence of transfected
p53, suggesting that the effect was dependent
upon transcriptionally
competent p53 in the cell (Fig.
6A, compare
lanes 2 and 5). The
effect of forskolin was likely mediated through
CREB (or a related
factor in the cell), as there is no evidence for
direct PKA phosphorylation
of p53 (
1). Additionally, since
pG13 carries only reiterated
p53 response elements upstream of a
minimal promoter, it is likely
that the observed stimulation by
forskolin was mediated through
these elements. Figure
6B shows that
forskolin treatment had little
or no effect on p53 levels produced in
the transfection assay.
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|
FIG. 6.
(A) Forskolin activates p53-dependent transcription in
vivo. The p53-responsive pG13-Luc reporter (400 ng) was cotransfected
into p53-null Jurkat T cells with the p53 expression plasmid (pC53-SN3)
(400 ng), as indicated. Forskolin (20 µM) and/or H-89 (5 µM) was
added (+) or not added () to the indicated transfection reactions.
(B) Forskolin had no effect on transfected p53 protein levels. Western
blot analysis of p53 derived from cells transfected with pC53-SN3 (400 ng), in the absence () and presence (+) of forskolin (20 µM). (C) A
CREB-responsive promoter responds appropriately to forskolin and H-89.
The reporter plasmid CRE-Luc (1 µg) (24) was transfected
in Jurkat T cells in the presence (+) or absence () of forskolin (20 µM) and/or H-89 (5 µM) as indicated. (D) Forskolin activates the
p53-responsive Bax promoter. The Bax-Luc reporter plasmid (400 ng) was
cotransfected in Jurkat T-cells with the p53 expression plasmid
(pC53-SN3) (400 ng) in the presence (+) or absence () of forskolin
(20 µM), as indicated. (E) The amino terminus of p53 is sufficient
for forskolin responsiveness. The Gal4 reporter plasmid (pGalTK-Luc)
(400 ng) was cotransfected in Jurkat T cells with the Gal4-p53
expression plasmids carrying either full-length p53 (pGal4-wtp53) or
the amino terminus of p53 (aa 1 to 52) (pGal4-p53N) (800 ng each)
(12). Reactions were either cotransfected with the catalytic
subunit of PKA (100 ng) or treated with forskolin (20 µM) as
indicated. Reported values for each transient-transfection experiment
are the average luminescence + the standard error (error bar) from
one experiment performed in duplicate. Each experiment was performed at
least twice.
|
|
Since forskolin is an activator of adenylate cyclase, we were
interested in determining more specifically whether the p53-dependent
transcriptional stimulation was mediated directly through PKA.
To
address this question, we simultaneously treated the transfected
cells
with both forskolin and the drug H-89, a specific pharmacological
inhibitor of PKA. H-89 appeared to abolish the forskolin stimulation
of
pG13-Luc, reducing transcription to the level observed with
transfected
p53 alone (Fig.
6A, lane 6). Figure
6C shows that
forskolin and H-89
were functioning correctly in the assay, as
both drugs appropriately
activated and inhibited transcription
initiated through a minimal cAMP
responsive promoter (lanes 1-3).
We were also interested in testing a natural p53-responsive promoter in
the transient-transfection assay, as pG13 is an artificial
promoter
construct and may not behave in a physiologically appropriate
fashion.
To address this question, we tested the effect of forskolin
on the
p53-responsive Bax promoter, linked to luciferase. Figure
6D shows that
expression from the Bax promoter was strongly stimulated
by forskolin,
in a p53-dependent manner (lanes 1 to
4).
In Fig.
4D, we present a co-IP experiment that provides evidence
suggesting that the amino terminus of p53 is involved in
interaction
with CREB. Based on this observation, we were interested
in testing
whether this region of p53 is sufficient for PKA-dependent
transcription in transient-transfection assays. We utilized a
truncation mutant of p53, which carried only the amino-terminal
52 aa
of the activation domain of p53, fused to the DNA binding
domain of
Gal4 (pGal4-p53N) (
12). Figure
6E shows that cotransfection
of Gal 4-wtp53 and Gal4-p53N similarly enhanced transcription
from the
Gal4-Luc reporter plasmid (compare lanes 3 and 5). This
observation is
not unexpected, as the amino terminus of p53 encompasses
the
primary activation domain of the protein. The addition of
forskolin to
the transfection reaction strongly enhanced Gal4-p53N-dependent
transcription, with the stimulation exceeding that observed with
the
full-length protein (Fig.
6E, compare lanes 3 and 4 with lanes
5 and
6). Cotransfection of the catalytic subunit of PKA, which
is
constitutively active for CREB phosphorylation, also produced
strong
pGAL4-p53N stimulation comparable to that observed with
forskolin (Fig.
6E, lanes 6 and 7). These data provide strong
supportive evidence for
an interaction between pCREB and the amino
terminus of p53, resulting
in PKA-dependent transcriptional stimulation.
The data also indicate
that p53 tetramerization is not required
for interaction with
pCREB.
To further address the biological relevance of the cAMP pathway on
p53-dependent transcription function, we tested the effect
of forskolin
on an endogenous p53-responsive target gene. We selected
the cell cycle
inhibitor gene p21 for our studies and examined
p21 mRNA levels in the
p53 wild-type breast cancer cell line MCF7.
We selected this cell line
as the p21 message was undetectable
in the Molt4 T-cell lines used
above. Northern blot analysis revealed
that treatment of MCF7 cells
with forskolin strongly stimulated
p21 mRNA synthesis in vivo
(fourfold) (Fig.
7A). Forskolin-induction
of p21 mRNA correlated with an increase in ATF/CREB phosphorylation
in
vivo, as demonstrated by Western blot analysis using an antibody
directed against the serine 133 phosphorylated form of CREB (Fig.
7B,
upper panel). We also detected a concomitant increase in p21
protein
levels, with little or no change in p53 protein levels
(Fig.
7B, middle
and lower panels). Interestingly, forskolin did
not increase p21
protein levels in two human T-cell lymphotrophic
virus type 1 infected
T-cell lines, where the presence of the
Tax protein inactivates the
endogenous wild-type p53 (data not
shown) (
9,
14,
30,
36).
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FIG. 7.
(A) Forskolin induces expression of the p21 gene. Shown
is the northern blot analysis of total RNA (15 µg) isolated from
untreated or 20 µM forskolin-treated MCF7 cells. RNA was hybridized
with a p21-specific probe or a GAPDH-specific probe as a loading
control. Specific transcripts are indicated. An RNA kilobase ladder and
18S and 28S rRNAs are shown at left. (B) CREB phosphorylation
correlates with p21 expression. Western blot analysis of pCREB
(anti-phosphoserine 133-CREB) (upper panel), p21 (gift from J. Wade
Harper) (middle panel), and p53 (DO-1) (lower panel) was performed
following a time course of 20 µM forskolin treatment of MCF7 cells.
Protein standards (in kilodaltons) are shown at left.
|
|
| |
DISCUSSION |
Deciphering the mechanism(s) of p53 function in the cell has been
one of the most intensively studied areas of modern biology. This focus
derives from the critically important role p53 plays in genome
surveillance and suppression of oncogenic transformation. Understanding
the role of p53 as a transcription factor and the identification of
p53-responsive target genes have greatly advanced our understanding of
p53 function; however, many of the molecular events that contribute to
p53 transcriptional activity remain elusive. The recent identification
of a direct p53-CBP interaction provides insight into the
transcriptional mechanisms that govern p53 function (5, 16, 26,
32, 36). In this study, we demonstrate the convergence of the PKA
signaling pathway on p53 coactivator recruitment, delineating a novel
mechanism of p53 coactivator utilization. We report the unexpected
discovery that PKA phosphorylation of CREB at Ser133
results in p53-dependent, indirect tethering of CBP to p53-responsive genes.
Our studies support a model where the formation of a ternary complex,
containing p53, pCREB, and CBP, facilitates transcriptional activation
of p53 target genes. In the ternary complex, pCREB serves as a
molecular bridge between p53 and CBP. Since the complex is phosphate
dependent, pKID likely makes the primary, and possibly exclusive,
contacts with KIX (31). Concomitantly, the bZIP domain interacts with residues located within the amino terminus of p53, without detectably interacting with the DNA. This interaction leaves
the DNA binding domain of p53 available, allowing p53 to deliver the
entire coactivator-containing complex to the promoters of
p53-responsive genes. A schematic illustrating these interactions is
shown in Fig. 8.
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FIG. 8.
Model showing the ternary complex, containing CBP,
pCREB, and p53, assembled on a p53-responsive promoter.
|
|
Our experiments support the idea that the ternary complex is strongly
stabilized by a direct interaction between p53 and CREB. The
possibility that p53 also contacts KIX in this complex cannot be
excluded; however, our evidence supports the CREB-p53 interaction as
the primary mode of p53 stabilization in the ternary complex. Specifically, we show that the amino terminus of p53, which carries the
activation domain of the protein, is involved in direct interaction with CREB. We show that an antibody against the amino terminus of p53
blocks complex formation between p53 and CREB, and we supply evidence
showing that the amino-terminal 52 aa of p53 are sufficient for
mediating cAMP responsiveness in vivo. Since we demonstrate that the
p53 double point mutant (L22Q-W23S) is fully active for interaction
with CREB in vitro, these experiments imply that other residues within
the amino terminus of p53 must participate in the interaction.
Therefore, when p53 is in complex with CREB, it may be unavailable for
direct coactivator interactions, as previous studies have shown that
the activation domain of p53 directly contacts CBP (16, 36).
Since p53 binds to DNA as a tetramer, it is possible that individual
monomers participate in a combination of separable contacts with CREB
and/or various domains of CBP, generating a highly complex regulatory response.
The identification of this unique ternary complex also has implications
for CREB-regulated transcription, as the binding of the bZIP domain to
p53 would likely abolish the DNA binding properties of the protein.
Therefore, under conditions of p53 activation, pCREB may be diverted
from CRE-responsive genes to p53-responsive genes. Although the
physiological circumstances leading to costimulation of these pathways
is not known, there is evidence that UV irradiation induces CREB
phosphorylation at Ser133 (19); thus, pCREB and p53 may synergize in response to a UV-induced signal transduction pathway. More importantly, the PKA pathway of p53-activated
transcription may represent an incomplete picture of this new model of
p53 transcription function, as a number of other kinases, including AKT
and pp90rsk, phosphorylate CREB at Ser133
(3, 8, 13, 37).
Our observation that the bZIP domain of CREB participates in the
interaction with p53 raises the question of whether additional bZIP-containing transcription factors are competent for p53 binding. Evidence supporting this idea comes from the co-IP assay (Fig. 4D),
where we detected up to four ATF/CREB immuno-reacting family members.
It is likely that one of these proteins was the cellular transcription
factor ATF-1, which shares a high degree of sequence similarity with
CREB (and cross-reacts with the anti-CREB antibody). It is also
possible that additional bZIP proteins, outside of the ATF/CREB
family, may also bind to p53, thus expanding the repertoire of
cellular proteins that may partner with p53 and regulate
p53-dependent transcriptional activation. These might include
components of the AP-1 complex, c-fos and c-jun, and the c/EBP family
of transcription factors
each in complex with a coactivator. If this
prediction is correct, it would suggest that the p53-pCREB interaction
characterized herein may represent a prototype of a much more general
mechanism that exerts precise control of p53 transcription function.
The observations reported in this study are very reminiscent of a
recent study showing that the bZIP transcription factor CHOP
participates in transcriptional activation via protein-protein interactions with the AP-1 complex (35). CHOP appears to be recruited to preexisting, DNA-bound AP-1 complexes through a direct tethering mechanism. Similar to the case with CREB, the bZIP domain of
CHOP is required, and it appears to be directly involved in protein-protein interaction with the AP-1 complex. The bZIP protein ATF-6 has also been shown to function in a similarly unusual fashion (39). ATF-6 interacts directly with the activation domain of serum response factor, contributing to serum stimulation of the c-fos promoter. Although the bZIP has not been directly
implicated in the ATF-6/serum response factor protein-protein
interaction, it is provocative that so many bZIP proteins appear to be
involved in this unusual tethering mechanism.
Together, the emerging evidence suggests that transcription factors may
function in unexpected ways, assembling vertically, as well as
horizontally, on target promoters, and exerting multilayered transcriptional responses. The interplay between the interacting transcription factors and their associated coactivators may serve to
precisely modulate responses to external stimuli, impacting decisions
that control cellular differentiation, oncogenesis, and programmed cell death.
| |
ACKNOWLEDGMENTS |
H.A.G. and I.L. contributed equally to this work.
We are grateful to C.-Z. Giam for providing the GST-CREB-His6
expression plasmid, Tom Shenk for providing the Gal4 DBD-p53 expression
system, Xinbin Chen for the p53-inducible cell line, J. Wade Harper for
the anti-p21 antibody, and Anne Brauweiler for construction of the CREB
deletion mutants.
This work was supported by INSERM (I.L.) and NIH CA80002.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry and Molecular Biology, Colorado State University, Fort
Collins, CO 80523-1870. Phone: (970) 491-0420. Fax: (970) 491-0494. E-mail: jnyborg{at}lamar.colostate.edu.
| |
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Molecular and Cellular Biology, July 2000, p. 4849-4858, Vol. 20, No. 13
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Abstract
Introduction
