Laboratoire Oncogenèse,
Différenciation et Transduction du Signal, CNRS UPR 9079, Institut André Lwoff, Villejuif,
France,1 and Department of Biochemistry,
Technion-Israel Institute of Technology, Haïfa 31096, Israel2
Received 13 December 2000/Returned for modification 22 January
2001/Accepted 7 May 2001
Acetylation is emerging as a posttranslational modification of
nuclear proteins that is essential to the regulation of transcription and that modifies transcription factor affinity for binding sites on
DNA, stability, and/or nuclear localization. Here, we present both in
vitro and in vivo evidence that acetylation increases the affinity of
myogenic factor MyoD for acetyltransferases CBP and p300. In
myogenic cells, the fraction of endogenous MyoD that is acetylated was
found associated with CBP or p300. In vitro, the interaction between
MyoD and CBP was more resistant to high salt concentrations and was
detected with lower doses of MyoD when MyoD was acetylated.
Interestingly, an analysis of CBP mutants revealed that the interaction
with acetylated MyoD involves the bromodomain of CBP. In live cells,
MyoD mutants that cannot be acetylated did not associate with CBP or
p300 and were strongly impaired in their ability to cooperate with CBP
for transcriptional activation of a muscle creatine kinase-luciferase
construct. Taken together, our data suggest a new mechanism for
activation of protein function by acetylation and demonstrate for the
first time an acetylation-dependent interaction between the bromodomain
of CBP and a nonhistone protein.
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INTRODUCTION |
Acetylation of histone or
nonhistone proteins is emerging as a central process in transcriptional
activation (4). Nuclear histone acetyltransferases
(HATs) such as GCN5 (6), PCAF (40), and CBP
and p300 (22) are transcriptional coactivators (18, 39). Their mode of action is not yet fully understood. They are
able to acetylate histones on lysine residues located in the N-terminal
histone tails, which protrude from the core nucleosome (38). Histone acetylation is linked to transcriptional
activation (33) and participates in the nucleosomal
remodeling that accompanies gene activity.
In vitro, HATs are also able to acetylate nonhistone proteins, in
particular, general transcription factors such as TFIIE and TFIIF
(13) and numerous sequence-specific transcription factors
(5, 11, 16, 20, 31), including myogenic factor MyoD
(28). MyoD is a transcription factor of the myogenic basic helix-loop-helix family that is central to the process of muscle cell
differentiation (7) and that functions by transactivating muscle-specific promoters (36). In vitro, MyoD is
acetylated by two HATs, CBP or p300 and PCAF, which are both required
for MyoD transactivating activity (25, 42). CBP and p300
are homologous proteins (8; Z. Arany, W. R. Sellers,
D. M. Livingston, and R. Eckner, Letter, Cell
77:799-800, 1994) that are found in large multimolecular
complexes. They have several highly homologous domains through which
they interact with a wide variety of sequence-specific transcription
factors and other proteins. In particular, CBP and p300 directly
interact with the N-terminal transactivation domain of MyoD
(27). CBP and p300 also have in common a domain that displays an intrinsic HAT activity (3, 22). Moreover, CBP and p300 recruit other HATs such as PCAF (40). CBP and
p300, PCAF, and other HATs also share a domain of ill-defined function, the bromodomain, which is frequently associated with
chromatin-remodeling proteins (12).
Ectopically expressed (28) as well as endogenous
(24) MyoD is acetylated in live cells. In vitro, CBP and
p300 (24) and PCAF (28) acetylate MyoD on
lysines 99 and 102, two lysines located at the boundary of the DNA
binding/dimerization domain, the basic helix-loop-helix domain.
Acetylation increases MyoD activity on muscle-specific promoters
(28). The mechanism of this activation is not yet fully
understood but has been reported to involve increased binding to DNA
(28). We here show that, in myogenic cells, the fraction
of endogenous MyoD that is acetylated is associated with CBP, whereas
acetylation of free MyoD is undetectable. This result suggests that
acetylated MyoD shows a higher affinity for the HAT than does
nonacetylated MyoD. This hypothesis was confirmed by the analysis of
nonacetylatable MyoD mutants: these mutants do not form detectable
complexes with CBP or p300 in cells. The increased interaction of CBP
with acetylated MyoD was confirmed by in vitro experiments. Acetylation
of recombinant wild-type MyoD strongly increased its affinity for CBP
and p300, as indicated (i) by increased resistance of the complex to
high salt concentrations and (ii) by the fact that complex formation
required lower doses of acetylated MyoD than nonacetylated MyoD.
Acetylation had no effect on complex formation by MyoD point
mutants in which key acetylatable lysines (99 and 102) were replaced by
arginines. Analysis of CBP deletion mutants revealed that the
interaction with acetylated MyoD is mediated by the bromodomain of CBP.
The functional relevance of the interaction between acetylated MyoD and
CBP was assessed by transient transfection experiments. A nonacetylatable MyoD mutant did not cooperate as efficiently with CBP
to activate a muscle creatine kinase (MCK)-luciferase reporter construct as the wild-type MyoD molecule.
Taken together, our results lead us to propose a model in which
acetylation of MyoD lysines 99 and 102 triggers the recognition of the
acetylated lysines by the bromodomain of CBP, resulting in a
strengthened interaction between the HAT and MyoD. In our model, this
results in a more efficient recruitment of HAT complexes to muscle
promoters, where these enzymes then acetylate other substrates. In
support of this model, results of chromatin immunoprecipitation experiments indicated that myogenic terminal differentiation triggers histone H4 acetylation. In summary, our data suggest a new mechanism for protein activation by acetylation and demonstrate an
acetylation-dependent interaction between the CBP bromodomain and a
nonhistone protein.
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MATERIALS AND METHODS |
Cell cultures.
Myoblastic C2C12 cells and embryonic C3H
10T1/2 cells were maintained in Dulbecco's modified Eagle medium
(DMEM) (Gibco) supplemented with 15 and 10% fetal calf serum
(FCS; Dominique Deutcher), respectively. To induce terminal
differentiation, the cells were placed in differentiation medium (DMEM,
1% FCS). Phenotypic differentiation of C2C12 cells was maximal after
72 h.
Preparation of recombinant proteins and acetylation in
vitro.
The bacterial expression vectors containing wild-type MyoD
cDNA and all mutated species of MyoD were kind gifts from K. Breitschopf, A. Ciechanover, and S. Leibovich. BL21 (DE3)/pLysS
Escherichia coli cells were used for bacterial expression of
MyoD. Following induction with IPTG
(isopropyl-
-D-thiogalactopyranoside), cells were lysed and MyoD was precipitated by 0.6 M ammonium sulfate as
described previously (30). CBP mutants (glutathione
S-transferase [GST]-CBP 1-1891 and 1-1696) were prepared
as previously described (1, 2). The GST-CBP construct with
deleted bromodomain (deletion of amino acids [aa] 1099 to 1220) was
derived from GST-CBP 1-1696 by means of
XbaI-BsrgI restriction, fill-in with Klenow
polymerase, and ligation. The GST-bromodomain construct was obtained by
cloning the PCR fragment corresponding to aa 1068 to 1476 of CBP into the pGEMT-Easy vector (Promega), followed by
BamHI-EcoRI restriction and cloning into the pGEX
vector (Promega). The GST-bromodomain construct with substitutions of
alanine for V1115 and Y1125 was obtained from the GST-bromodomain
construct using the Quick Change mutagenesis kit (Stratagene). The
GST-C/H3 construct was obtained by cloning the PCR fragment
corresponding to aa 1619 to 1877 of CBP into the pGEX vector. p300 and
PCAF were produced in insect cells using a baculovirus-driven
expression system and standard procedures. The His-tagged p300 and p300
with deleted bromodomain were cloned from pBluescript constructs
(kind gift from W. Lee Kraus) by
NotI- HindIII restriction and ligation
into the pCMV eukaryotic expression vector.
Recombinant MyoD acetylation was carried out in vitro by incubating 2 to 4 µg of protein with 0.1 to 2 µg of recombinant HATs for 1 h at 30°C in a buffer containing 50 mM Tris, pH 7.5, 2 mM EDTA,
inhibitors of proteases (Complete; Boehringer Mannheim) and of
deacetylases (10 mM sodium butyrate; Sigma), and 1 mM acetyl coenzyme A
(CoA) per reaction.
Microinjection and myogenic conversion.
C3H 10T1/2 mouse
embryonic fibroblasts were seeded on coverslips placed into
35-mm-diameter tissue culture dishes (Nunc) at 7 × 104 cells per dish. Twenty-four hours later,
pEMSV-MyoD was microinjected into cells, together with increasing
amounts of pCMV-p300 or pCMV-p300 del Br and a mixture of 40,000- and
10,000-molecular-weight dextran-rhodamine, fixable (1% final
concentration; Molecular Probes), in a buffer containing 10 mM Tris, pH
7.5, and 100 mM KCl in a final volume of 10 µl. Six hours
after microinjection, cells were placed in differentiation medium.
After 48 h, cells were fixed with 2% paraformaldehyde, permeabilized with 0.5% Triton X-100, stained with a monoclonal antimyogenin antibody (F.5D; kind gift from W. E. Wright) followed by antimouse fluorescein isothiocyanate (Sigma), and analyzed by
fluorescence microscopy.
Semiquantitative GST pull-down.
Increasing amounts of MyoD
(2 to 100 ng/point) were incubated for 1 h at 30°C with 2 to 4 µg of GST-CBP or GST immobilized on agarose beads in Tris-EDTA
(TE) buffer containing protease inhibitors with or without
acetyl-CoA (1 mM; Sigma). TE buffer was chosen as the optimal buffer
for in vitro acetylation reactions. Note that nonspecific binding on
GST-coated beads was low in this buffer. Beads were washed three times
with TE supplemented with the concentrations of KCl indicated in
Fig. 2 and 3, and proteins were resolved by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and analyzed
by Western blotting with anti-MyoD antibodies (C-20; Santa Cruz
Biotechnology). In some experiments, the amount of GST protein was
verified using anti-GST antibodies (Z-5; Santa Cruz Biotechnology) and,
for the same protein, did not show any variation between samples (data
not shown).
For experiments illustrated in Fig. 4C to E, MyoD (5 µg) was
acetylated by incubation with GST-CBP immobilized on agarose beads in the presence of 1 mM acetyl-CoA (or was not acetylated, for
the negative controls) and then separated from the enzyme by
incubation in 2 M KCl (15 min at 30°C) followed by centrifugation. The supernatant, which contained free MyoD but no detectable amounts of
GST-CBP (as assessed by Western blotting), was diluted and incubated
for 15 min with beads coated with GST or with various GST-CBP mutants
and pretreated with 0.1% bovine serum albumin. Beads were washed with
1 M KCl followed by PBS; then the proteins were resolved by SDS-PAGE
and analyzed by Western blotting with anti-MyoD antibodies. The
presence of equal amounts of GST proteins in the lanes with acetylated
and nonacetylated MyoD was verified by Western blotting with anti-GST
antibodies (Z-5; Santa Cruz Biotechnology; data not shown).
Immunoprecipitation and Western blotting.
Immunoprecipitation and Western blotting were performed using standard
procedures. Immunoprecipitated proteins were collected on protein
G-agarose (Sigma). Beads were washed three times with phosphate-buffered saline (PBS). The samples were resolved by SDS-PAGE
and transferred to nitrocellulose membranes. Membranes were blocked
with PBS containing 10% dry milk, incubated with antibodies followed
by peroxidase-conjugated secondary antibodies (Sigma), and
developed using the Boehringer Mannheim LumiLight kit as recommended by
the manufacturer.
Acetylation of MyoD in CBP complexes was assessed by
immunoprecipitation of total cell extracts of differentiating (24 h) C2C12 myoblasts with anti-p300/CBP (NM11; Pharmingen). "Free" MyoD
was immunoprecipitated from the supernatant using anti-MyoD antibodies
(5.8A; Novocastra). Total MyoD was obtained by direct immunoprecipitation of MyoD from total extracts. All fractions were
analyzed by Western blotting using antiacetyllysine antibodies (Upstate
Biotechnology) and an anti-MyoD antibody (C-20; Santa Cruz Biotechnology).
Coimmunoprecipitation experiments were performed on extracts from
transfected cells. For expression in mammalian cells, MyoD cDNAs from
pT7-7 bacterial expression vectors (Sa) were subcloned into
pGEMT vector (Promega) and cloned into the EcoRI site of pEMSV-scribe (9, 32). CBP expression was driven by
pCMV2N3T CBP (26). Transfections were performed using
Lipofectamine (Life Technologies) or Polyfect (Qiagen), as described by
the manufacturer, in 10-cm-diameter dishes. Cells received
expression vectors (p2N3T CBP [20 µg], pCMV-p300, pCMV-p300 del Br,
pEMSV MyoD, or pEMSV MyoD mut2 [10 µg]) and 1 µg of
pRSV-gal as an internal standard for transfection efficiency and
were incubated overnight. Extracts were prepared 24 h later,
normalized by assaying -galactosidase activity using a kit from
Tropix, immunoprecipitated using anti-CBP antibodies (A-22; Santa Cruz
Biotechnology) or anti-p300 antibodies (N-15; Santa Cruz
Biotechnology), and analyzed by Western blotting using anti-MyoD
antibodies (5.8 A; Novocastra) and either anti-CBP/p300 antibodies
(NM11; PharMingen) or an anti-His antibody (H-3; Santa Cruz Biotechnology).
Transient transfection assays.
The C3H 10T1/2 cells were
seeded out on 12-well dishes (3 × 104 cells
per well) and transfected 24 h later by the calcium phosphate precipitation method. Cells received expression vectors for wild-type MyoD or mutant m2 (100 ng/well), together with 200 ng of
MCK-luciferase reporter vector/well and increasing doses of pCMV-CBP,
and were incubated overnight at 37°C. Extracts were prepared 36 h later, the luciferase activity was measured using the Luciferase
Assay System from Promega, and the expression of wild-type and mutant MyoD was controlled by Western blotting using an anti-MyoD antibody (C-20; Santa Cruz Biotechnology).
Chromatin immunoprecipitation.
C2C12 cells, either
continuously growing or after 24 h of differentiation, were fixed
using 1% formaldehyde in tissue culture medium for 7 min at 37°C.
Chromatin was prepared using a kit from Upstate Biotechnology according
to the recommendations of the manufacturer, with eight 10-s sonication
pulses at 10-s intervals, which yielded chromatin fragments of an
apparent size of 800 bp (as monitored on agarose gels; data not shown).
Equivalent amounts of chromatin, as assessed by visualizing serial
dilutions on agarose gels (data not shown), were immunoprecipitated
using an anti-acetylated histone H4 antibody (Upstate Biotechnology) or
irrelevant immunoglobulins (Sigma) for the control.
Formaldehyde-induced cross-linking was reversed (4 h at 65°C), and a
sequence of the MCK promoter or of the GAPDH
(glyceraldehyde-3-phosphate dehydrogenase) gene (as an internal
control) was detected by quantitative PCR. In this assay, a fixed
amount of immunoprecipitated DNA was amplified together with increasing
amounts of a competitor DNA amplified by the same primers.
The primers used were as follows: for MCK, 5'-GGATGAGAGCAGCCACTATG
(forward) and 5'-ACCATGGCAGAATTGACAGG (reverse),
yielding a 325-bp product corresponding to region 
1265 to 945 of
the promoter; for GAPDH, 5'-CCAATGTGTCCGTCGTGGATCT-3'
(forward) and GTTGAAGTCGCAGGAGACAACC-3' (reverse), yielding a
190-bp fragment.
The competitive heterologous DNA fragments were created by
amplification of irrelevant plasmids using composite primers.
Amplification products were analyzed on agarose gels.
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RESULTS |
Preferential association between acetylated MyoD and CBP in live
cells.
Endogenous MyoD is constitutively acetylated in myogenic
cells (24). A comparison of the fraction of MyoD that is
complexed to CBP or p300 and the fraction containing free MyoD revealed a nonrandom distribution (Fig. 1).
Extracts from C2C12 (a myogenic cell line) cells, sampled after 24 h in differentiation medium, were immunoprecipitated with anti-CBP/p300
antibodies (Fig. 1A, complexes), and the supernatant (in which CBP and
p300 could not be detected; data not shown) was immunoprecipitated with
anti-MyoD (Fig. 1A, free). In parallel, extracts were directly
immunoprecipitated with anti-MyoD antibodies (Fig. 1A, total). All
samples were analyzed by Western blotting for the presence of MyoD
using anti-MyoD antibodies and for the presence of acetylated proteins
using anti-acetylated lysine antibodies (Fig. 1B). Acetylated species
were detected only in the fraction of MyoD that was associated with
CBP. Although the free fraction contained the majority of cellular
MyoD, acetylation could not be detected in this fraction (Fig. 1B).
This result suggests that there is a preferential association between
acetylated MyoD and CBP and that MyoD acetylation, by CBP itself or by
other acetyltransferases, increases MyoD's affinity for CBP.
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FIG. 1.
Preferential association between acetylated MyoD and CBP
and p300. Myogenic cell extracts were immunoprecipitated (ip) as shown
in panel A and analyzed by Western blotting (wb) (B) using
anti-acetylated lysine or anti-MyoD as indicated. irr,
immunoprecipitation using an irrelevant antibody as a negative
control.
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Acetylated lysines of MyoD are required for interaction with CBP in
cells.
To confirm the hypothesis that acetylated lysines of MyoD
are required for interaction with CBP, the interaction between
CBP and MyoD point mutants which have lost lysines 99, 102, and 104, and which thus cannot be acetylated (24, 28), was analyzed (Fig. 2). In these experiments, wild-type
or mutant MyoD was ectopically expressed in C3H 10T1/2 (nonmuscle)
cells together with CBP and extracts were analyzed by
immunoprecipitation using anti-CBP antibodies, followed by Western
blotting using an anti-MyoD antibody (Fig. 2A). In contrast to the
wild-type molecule, the mutants were barely detectable in CBP
complexes. This impaired interaction might result from the lack of
acetylation of the mutants. Alternatively, the mutated lysines could be
directly or indirectly involved in the interaction with CBP. To rule
out this possibility, the interaction between mutant MyoD and CBP was
analyzed in vitro and compared to that for the nonacetylated wild-type
protein. We first analyzed the resistance of the CBP-MyoD complex to
high salt concentrations. An excess of recombinant MyoD was incubated
with GST-CBP-coated beads, and beads were washed with increasing
concentrations of KCl. Under these conditions, both wild-type and
mutated MyoD bound to CBP. In addition, the salt concentrations at
which the complex was disrupted (above 0.6 M) for the wild-type and
mutated forms of MyoD were similar (Fig. 2B). This result was confirmed
using a semiquantitative GST pull-down assay in which increasing
amounts of MyoD were incubated with GST-CBP-coated beads. After being washed, beads were analyzed by Western blotting using an anti-MyoD antibody. The amounts of MyoD required to detect the protein in the
complex were similar for mutated and wild-type MyoD (Fig. 2C),
suggesting that the mutant displays an affinity for CBP that is similar
to that displayed by the nonacetylated wild-type molecule. These
results strongly suggest that MyoD's acetylatable lysines are not
themselves directly involved in the interaction with CBP. Thus, when
nonacetylated, the two forms of MyoD have similar affinities for CBP,
and the observed difference between the mutant and the wild-type
proteins in live cells is most likely due to the absence of acetylation
of the mutant protein in vivo.
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FIG. 2.
Nonacetylatable MyoD mutants do not associate with CBP
in cells. Mutants used were m2, in which lysines 99, 102, and 104 were
replaced by arginines, and m5, in which lysines 99, 102, 104, 112, 124, and 133 were replaced by arginines. (A) C3H 10T1/2 cells were
transfected with expression vectors for wild-type (wt) or point-mutated
(m2 or m5) MyoD together with an expression vector for wt CBP 1-2441. A
MyoD empty vector vehicle was used in negative controls (co). Extracts
from transfected cells were immunoprecipitated (ip) using an anti-CBP
antibody or an anti-MyoD antibody as indicated. MyoD and CBP were
detected by Western blotting (wb), as indicated. (B) Nonacetylated wt
or mutant MyoD (m2) was incubated with GST-CBP-coated beads for 1 h and washed with TE buffer containing the indicated concentrations of
KCl. Beads were analyzed by Western blotting using anti-MyoD
antibodies. (C) Indicated doses of nonacetylated MyoD (wt or mutated)
were incubated in TE buffer with GST-CBP-coated beads. Beads were
analyzed by Western blotting using anti-MyoD antibodies. Input,
the amount of each MyoD protein, estimated as 2 ng (1/25 of maximal
amount used in this experiment).
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Acetylation increases MyoD affinity for CBP and p300 in vitro.
To further demonstrate that acetylation increases MyoD affinity for
CBP, the affinities of acetylated and nonacetylated MyoD were directly
compared. First, the resistance of CBP-MyoD complexes to stringent salt
conditions was assessed. Whereas the interaction between nonacetylated
MyoD and CBP was disrupted above 0.6 M KCl (Fig.
3A and B), the interaction between CBP
and acetylated MyoD was readily detectable at 1.2 M KCl. This effect
could be due to acetylation of MyoD or, alternatively, to the
autoacetylation of CBP. The latter hypothesis was ruled out by
experiments using a nonacetylatable MyoD mutant (Fig. 3A and B). This
mutant did not show any increased resistance to high salt concentration
upon similar treatment.
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FIG. 3.
Acetylation increases MyoD affinity for CBP in vitro.
(A) Equivalent amounts of wild-type (wt) and point-mutated (m2) MyoD
were incubated with GST-CBP 1-2441-coated beads for 1 h, with or
without acetyl-CoA (1 mM), and washed with TE buffer containing the
indicated concentrations of KCl. GST-coated beads were used as a
negative control. (B) Autoradiograms of the blots shown in panel A were
analyzed by densitometry. Open circle, nonacetylated MyoD; solid
square, acetylated MyoD. Increasing doses (2, 10, and 50 ng) of
recombinant MyoD were incubated with GST-CBP absorbed onto
glutathione-coated beads in the presence or absence of acetyl-CoA. The
presence of MyoD in association with CBP was detected by Western
blotting as described for Fig. 2.
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Second, we used a semiquantitative GST pull-down assay, in which
increasing amounts of MyoD were incubated with GST-CBP-coated beads, in
the presence or (for the nonacetylated samples) absence of acetyl-CoA.
For the wild-type molecule, about fivefold less acetylated MyoD (Fig.
3B) than nonacetylated MyoD was needed to detect an association with
CBP. No such effect was observed with a nonacetylatable MyoD mutant.
Note that the anti-MyoD antibody detects acetylated and nonacetylated
MyoD with equivalent efficiencies (24). An analysis of
point mutants indicated that the two acetylatable lysines of MyoD,
lysine 99 and lysine 102 (24), were involved in the
formation of the complex with CBP, although mutation of lysine 99 alone
decreased significantly the strength of the interaction (data not
shown). Taken together, these in vitro results indicate that MyoD
acetylation strengthens its interaction with the HAT CBP.
The CBP bromodomain is involved in the interaction with acetylated
MyoD.
To determine the domains of CBP involved in the interaction
with acetylated MyoD, several fragments of CBP were analyzed in the
semiquantitative GST pull-down assay. Note that this assay was designed
only to compare the binding of acetylated and nonacetylated MyoD and
not to compare the affinities of distinct CBP mutants for MyoD. The
C-terminal part of CBP was found to be dispensable for the selective
interaction with acetylated MyoD (Fig.
4B): CBP 1-1891 interacted more strongly
with acetylated than with nonacetylated MyoD. Likewise, deletion of
CBP's major domain of interaction with MyoD, the C/H3 domain, did not
change the behavior of CBP: this mutant also interacted more strongly
with acetylated MyoD than with nonacetylated MyoD (Fig. 4B). This
indicates that selective recognition of the acetylated form of MyoD
does not require the CBP C/H3 domain.
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FIG. 4.
CBP bromodomain is involved in the interaction with
acetylated MyoD. (A) Diagram of the CBP molecule, showing the C/H3
domain, bromodomain, and HAT domain. (B) Increasing doses (2, 10, and
50 ng) of recombinant MyoD were incubated with GST-CBP absorbed onto
glutathione-coated beads in the presence or absence of acetyl-CoA; the
presence of MyoD in association with CBP was detected by Western
blotting. wt, wild type. (C to F) MyoD was incubated with wt CBP in the
presence of acetyl-CoA (Ac-CoA) (or in the absence of Ac-CoA for the
controls, as indicated), isolated from the enzyme, and used in
a GST pull-down assay with beads coated with the indicated CBP mutants;
the presence of MyoD in association with CBP was detected by Western
blotting.
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We next tested the hypothesis of CBP bromodomain involvement in the
interaction with acetylated MyoD. For that purpose, we used an indirect
assay, in which the detection of protein-protein interactions was
uncoupled from the acetylation step, hence allowing the use of
HAT-negative fragments of CBP. In this assay, MyoD was incubated with
beads coated with wild-type CBP in the presence of acetyl-CoA (or in
its absence for the negative controls). MyoD was then separated from
the beads by incubation in 2 M KCl and subsequently used in a regular
GST pull-down with beads coated with various fragments of CBP (see
Materials and Methods). CBP 1-1696 retained acetylated MyoD, whereas
association of nonacetylated MyoD was undetectable under the conditions
used (Fig. 4C), confirming the difference of affinity between the two
forms of MyoD. Deletion of the bromodomain abrogated the difference
between acetylated and nonacetylated MyoD (compare CBP 1-1696 and CBP
1-1696
Br; note that more of the CBP 1-1696Br protein was used in
this assay [data not shown], resulting in a higher background binding
of nonacetylated MyoD to this mutant). This result suggests that the
bromodomain is involved in the recognition of acetylated MyoD. To
further test this hypothesis, a fragment of CBP which includes only the
bromodomain (CBP 1079-1457) was tested in the same assay. The
bromodomain selectively retained acetylated MyoD but not the nonacetylated species (Fig. 4D). Mutations of highly conserved residues
in the CBP bromodomain abrogated the selective interaction with
acetylated MyoD (Fig. 4E). In contrast, the C/H3 domain recognized acetylated and nonacetylated MyoD with the same efficiency (Fig. 4F).
Taken together, these data indicate that the bromodomain is necessary
and sufficient for interaction with acetylated MyoD.
The bromodomains of CBP and p300 are involved in physical
and functional interaction with MyoD.
Taken together, our results
suggest that, in live cells, the interaction between CBP or p300 and
MyoD occurs only when MyoD is acetylated, and involves the bromodomain.
Deletion mutants were used to test this hypothesis. For these
experiments, we had to use a p300 deletion mutant instead of a CBP
deletion mutant due to the impaired HAT activity of the corresponding
CBP construct's product. Note that CBP and p300 belong to the same
family of HATs and are highly homologous (Arany et al., letter). In
addition, ex vivo, they cannot be distinguished from a functional point of view. This is specifically true for myogenic differentiation, for
which, to our knowledge, no functional differences have ever been
demonstrated. In particular, both CBP and p300 acetylate MyoD with
identical functional consequences (24).
Coimmunoprecipitation experiments performed on extracts from cells
transfected with expression vectors for wild-type MyoD and p300
indicated that deletion of the p300 bromodomain strongly decreased
p300's ability to physically interact with MyoD (Fig.
5A), although the mutant was expressed at
higher levels than the wild-type molecule (Fig. 5B). This decreased
interaction was accompanied by a decreased ability to cooperate with
MyoD in a myogenic conversion assay. Nonmuscle cells (C3H
10T1/2) were microinjected with expression vectors for MyoD and
CBP or p 300, either wild type or with the bromodomain deleted.
Expression of myogenin, a marker of muscle cell differentiation, was
assayed 48 h later by immunofluorescence (data not shown). In this
assay, p300 and CBP had identical effects on myogenin expression (Fig.
5C): both proteins increased myogenin induction by MyoD. In contrast,
the deletion mutant had hardly any effect (Fig. 5C). These data
indicate that the bromodomain of CBP is involved in the cooperation
between CBP and MyoD. Although we cannot rule out the hypothesis that
the bromodomain is also involved through its ability to recognize the
nucleosomal histones (10, 17), taken together these data
on the physical (A) and functional (C) interaction of CBP and MyoD
clearly indicate that the bromodomain participates in the interaction
between the two proteins in live cells.
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FIG. 5.
CBP bromodomain is involved in physical and functional
interaction with MyoD. (A) Nonmuscle cells (C3H 10T1/2) were
transfected with expression vectors for MyoD and p300, either wild type
(wt) or with the bromodomain deleted. Extracts were immunoprecipitated
(ip) with an anti-p300 antibody and analyzed by Western blotting (wb)
using an anti-MyoD antibody. (B) Expression of transfected proteins.
Extracts of transfected cells were immunoprecipitated and analyzed by
Western blotting using the indicated antibodies. (C) C3H 10T1/2 cells
were microinjected with expression vectors for MyoD and for p300,
either wt or with the bromodomain deleted, together with a
rhodamine-coupled injection marker. After 40 h in differentiation
medium, cells were fixed and immunostained with an antimyogenin
antibody. Shown is the fraction of injected cells (rhodamine positive)
which express myogenin;  , wt CBP;  , wt p300;  , p300 delta
Br.
|
|
Nonacetylatable MyoD mutants show an impaired cooperation with
CBP.
MyoD acetylation has been reported to increase MyoD binding
to DNA (28) and/or seems to modify MyoD's affinity
for CBP (this study). To demonstrate that the latter effect is central
to MyoD activity, we examined whether a MyoD mutant that cannot be
acetylated is able to cooperate with CBP. Cells were transfected with a
reporter construct in which the luciferase gene is under the control of muscle-specific promoter MCK together with expression vectors for
wild-type or mutant (m2) MyoD and increasing doses of an expression vector for CBP (Fig. 6). In the absence
of CBP, the m2 mutant was not as efficient as the wild-type molecule in
activating MCK, as previously reported (24, 28). The
activity of the wild-type molecule was increased in a dose-dependent
manner by the expression of CBP, which in the absence of MyoD did not
have any effect on promoter activity (data not shown). This
cooperation, striking at the highest dose tested, was also seen
at lower doses of the CBP expression vector (e.g., 0.5 µg; Fig. 6A
and B). In contrast, and although the levels of expression of
the mutant and the wild-type molecule were similar (Fig. 6C), no
cooperation between the mutant and CBP at low doses of the CBP
expression vector was evident (Fig. 6A and B). A significant activation
of the MCK reporter by the mutant, however, was observed at high doses.
Three- to fivefold more CBP was required to achieve equivalent levels
of activation with the mutant form of MyoD than was necessary with the
wild-type molecule. Thus, the mutant is deficient in its ability to
cooperate with CBP, but cooperation can be rescued, at least partially,
by high doses of the HAT. This result suggests, not that the binding to
DNA is the limiting step for the mutant's activity, but rather that
lack of MyoD acetylation is detrimental to its cooperation with CBP,
most likely due to a low affinity for the HAT itself.
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FIG. 6.
Impaired cooperation between nonacetylatable MyoD and
CBP mutants. Nonmuscle cells (C3H 10T1/2) were transfected with an
MCK-luciferase reporter construct, together with a pEMSV MyoD
expression vector (100 ng) and indicated doses of CMV-CBP. Results of a
representative experiment are shown. (A) Luciferase activity was
measured in duplicate. r.l.u., relative light units; wt wild type. (B)
Means of three independent experiments ± standard deviations are
shown as the fold inductions by CBP (ratio between r.l.u. obtained in
the presence of CBP and r.l.u. obtained in its absence).  , wt MyoD;
, m2. (C) Western blot analysis of MyoD expression.
|
|
MyoD is not the only target of HATs for endogenous muscle promoter
activation.
A likely interpretation of our results is that
acetylated MyoD acts as a strong bridge between the HAT enzymes and
muscle-specific promoters and helps to establish a stable recruitment
of the enzymes to the promoters. The functional consequence of HAT's
stable recruitment was expected to be the acetylation of other
proteins bound to these promoters such as the histones. In order to
test this hypothesis, histone acetylation on the MCK promoter was
monitored using a chromatin immunoprecipitation assay. In these
experiments, equivalent amounts of chromatin (Fig.
7D) were prepared from C2C12 myoblasts, either continuously growing or after 24 h in differentiation
medium, and immunoprecipitated using either an antibody directed
against acetylated histone H4 (lysine 5, 8, 12, and 14) or an
irrelevant antibody as a control. A quantitative PCR assay was used to
detect the MCK promoter in the immunoprecipitates. Results (Fig. 7)
indicate a significant increase in the amount of MCK promoter retained by the anti-acetylated H4 antibody in extracts from differentiated cells over the amount retained in extracts from growing cells. The MCK
promoter was not retained by an irrelevant antibody. In addition, the
GAPDH promoter, used as an internal control, did not demonstrate any
modulation in histone H4 acetylation in differentiating cells
compared with that in growing myoblasts. These results indicate that
histone H4 tails associated with the MCK promoter are specifically acetylated during myoblast differentiation and thus that a HAT activity
is recruited to this promoter in differentiating cells.
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FIG. 7.
MCK-associated histone H4 is acetylated on terminal
differentiation. Chromatin was extracted from C2C12 muscle cells,
either continuously growing or else differentiating, as indicated.
Equivalent amounts of chromatin (as assessed by gel analysis of
dilutions; data not shown) were immunoprecipitated using an
anti-acetylated (ac) histone H4 (A and C) or an irrelevant antibody
(ab) as a control (B). The MCK promoter (A and B) and the GAPDH
promoter as an internal control (C) were detected by quantitative PCR
analysis using increasing doses of a competitor DNA (no DNA
[]; 100 ag; 1, 10, and 100 fg; and 1 pg) amplified by the
same primers. Arrows, bands corresponding to the MCK or GAPDH
amplification products, as well as the bands corresponding to the
competitor (comp) amplification products. (D) Nondenaturing gel
analysis of serial dilutions of chromatin used for immunoprecipitation
stained by ethidium bromide.
|
|
| |
DISCUSSION |
MyoD, like other sequence-specific transcription factors, seems to
be regulated by acetylation. The mechanism through which acetylation of
MyoD increases its activity is not yet fully understood. MyoD
acetylation by PCAF increases its affinity for DNA, at least for
MyoD-MyoD homodimers (28). However, homodimers are not the active species in muscle cells (19, 21), and thus the
significance of this observation is not clear. Our results support an
alternative hypothesis in which the acetylation of MyoD increases the
stability of the complex formed between MyoD and the HAT CBP. This is
concluded essentially from the analysis of acetylated MyoD in live
cells and from results of in vitro testing. Such an effect of
acetylation has been recently suggested for another transcription
factor (29). Concerning the mechanism of this
stabilization, several alternative hypotheses must be considered. The
acetylated lysines might be part of MyoD's domain of interaction with
CBP, and the acetylation might facilitate this interaction, for
example, through neutralization of repulsive charges. However, the
region of MyoD in which the acetylated lysines are located has not been
reported as being involved in the interaction with CBP or p300, for
which a 100-aa N-terminal fragment seems to be sufficient
(27). Moreover, point mutation of the lysines did not
impair the apparent affinity of nonacetylated MyoD for CBP in vitro
(Fig. 2). In addition, the interaction between CBP and acetylated MyoD
did not require the C/H3 domain, the major domain of CBP for
interaction with the N-terminal region of MyoD (Fig. 4). As an
alternative hypothesis, lysine acetylation could result in a
conformational change of the MyoD molecule that would positively affect
its interaction with CBP. Finally, the acetylated lysines themselves
could provide a recognition motif for CBP (Fig.
8). The last hypothesis is supported by
the fact that the CBP bromodomain is involved in the interaction. In
this regard it is significant that X-ray analysis of the PCAF bromodomain demonstrated that this domain selectively interacts with
acetylated lysines (10). A likely hypothesis is thus that the interaction between the CBP bromodomain and acetylated lysines in
MyoD provides additional links that strengthen the interaction between
the two proteins (Fig. 8). In this model, the bromodomain would be a
domain of protein-protein interaction that selectively recognizes amino
acid sequences in which lysines are acetylated, as previously suggested
(37), much as the SH2 domains are domains that recognize
amino acid sequences in which a tyrosine is phosphorylated. Our data
provide the first experimental evidence for such a selective interaction between a nonhistone protein and the bromodomain: we show
that the bromodomain of CBP, in the absence of the rest of the
molecule, discriminates between acetylated and nonacetylated MyoD and
selectively binds the acetylated but not the nonacetylated form. This
result demonstrates that such a mechanism is not restricted to histones
but rather may be more general.
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FIG. 8.
A model for the association between acetylated MyoD and
CBP (see Discussion). Br, bromodomain. Curved arrows, substrate
acetylation by the HAT; asterisks, acetylated lysines on
MyoD.
|
|
The interaction between recombinant MyoD and recombinant PCAF was
weaker than that between MyoD and CBP and, in the absence of CBP, was
not significantly strengthened by MyoD acetylation (27; A. Polesskaya and A. Harel-Bellan, unpublished observations). However, it
is likely that, in myogenic cells, PCAF is strongly associated with
acetylated MyoD through CBP. Indeed, CBP-PCAF complexes are easily
detected in muscle cells (A. Polesskaya and A. Harel-Bellan,
unpublished observation), suggesting that significant proportions of
the two molecules are associated in these cells. Moreover, the binding
of MyoD and that of PCAF to CBP are not mutually exclusive, and a
trimolecular complex could potentially exist (27). The
stabilization of the CBP-MyoD interaction thus likely facilitates the
formation of a multimolecular complex that includes PCAF.
Mutation of acetylation sites in MyoD strongly decreased the ability of
the molecule to functionally cooperate with CBP (Fig. 6). The mutant,
however, was at least partly rescued by a large excess of CBP,
suggesting that its defect resides in the lack of a strong interaction
with CBP and the HAT complexes. A strong interaction between MyoD and
the HATs might have several consequences. Given that sequence-specific
transcription factors have been shown to recruit HAT complexes to
target promoters (34), a strong interaction between CBP
and acetylated MyoD is likely to result in a more efficient recruitment
of the HATs to muscle-specific promoters. In that regard, it should be
noted that CBP and p300, which are central to the activity of a wide
variety of transcription factors, are thought to be present in limiting
amounts in cells. Competition of transcription factors for these
pivotal coactivators could affect gene regulation (15,
35). In support of this hypothesis is the observation that
cbp is subjected to major gene dosage effects in mice
(41) and in humans (23). A strong interaction between MyoD and the HATs could thus help in maintaining an adequate fraction of the HATs complexed to MyoD in muscle cells. In this regard,
it should be noted that the muscle differentiation program is
irreversible, and a strong interaction between MyoD and the HATs could
play a role in this phenomenon. The HAT-MyoD complex is likely to be
strongly bound to muscle-specific promoters such as MCK, where a
significant increase in the acetylation of histone H4 is observed
during terminal differentiation of myoblasts (Fig. 7). Acetylation of
core histones has been reported to have a very short half-life
(14), and permanent reacetylation of histones is likely to
be necessary to maintain an "open" structure on the promoter. A
strong association between acetylated MyoD and CBP or p300 might thus
be crucial to retaining the HAT complex on muscle promoters and
maintaining, locally, a state of hyperacetylation.
In summary, our results lead us to propose a model in which MyoD
acetylation allows the sequestration of HAT complexes to muscle-specific promoters on which they acetylate other substrates such
as histones. These data reveal a new mechanism for transcription factor
activation by acetylation. In addition, they provide the first
experimental evidence for a selective interaction between an acetylated
nonhistone protein and a bromodomain, leading to the generalization of
a hypothesis previously formulated for the function of these domains.
This work was supported by grants from the Association pour la
Recherche sur le Cancer and from the Association Française contre
les Myopathies to A.H.-B. and from the European 5th PCRDT (grant QLRT
1999-00866) to A.H.-B. A.P. was awarded a fellowship from the
Federation of European Biochemical Societies (FEBS).
We thank L. Cabanie for the preparation of recombinant proteins, V. Ogryzko, K. Breitschopf, A. Ciechanover, W. Lee Kraus, and S. A. Leibovitch for the kind gift of reagents, and L. L. Pritchard for
helpful discussions and critical reading of the manuscript.
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Abstract
Introduction
