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Previous Article | Next Article 
Journal of Virology, July 2000, p. 5872-5879, Vol. 74, No. 13
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
AMF-1/Gps2 Binds p300 and Enhances Its Interaction
with Papillomavirus E2 Proteins
Yu-Cai
Peng,
David E.
Breiding,
Francis
Sverdrup,
James
Richard, and
Elliot J.
Androphy*
Department of Dermatology, New England
Medical Center, Tufts University School of Medicine, Boston,
Massachusetts 02111
Received 18 January 2000/Accepted 4 April 2000
 |
ABSTRACT |
The cellular protein AMF-1 (Gps2) positively modulates gene
expression by the papillomavirus E2 protein (D. E. Breiding et al., Mol. Cell. Biol. 17:7208-7219, 1997). We show here that AMF-1 also binds the transcriptional coactivator p300 in vitro and in vivo.
E2 interacted weakly with p300. These observations led to a model in
which AMF-1 recruits p300 into a complex with E2. Cotransfection of
AMF-1 or p300 stimulated levels of E2-dependent transcription, while
cotransfection of both AMF-1 and p300 showed an additive effect. The
functional significance of p300 recruitment for E2 transactivation was
evidenced by repression of E2-activated transcription by adenovirus
E1A, which inhibits both coactivator and acetylase activities of p300.
Antibodies to AMF-1 or E2 immunoprecipitated histone acetylase activity
from cell lysates. Western blotting using antibody against
acetyl-lysine failed to detect acetylation of AMF-1 or E2 in complex
with p300. These results suggest that AMF-1 facilitates the recruitment
of p300 and its histone acetylase activity into complexes with E2 and
represents a novel mechanism of transcriptional activation.
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INTRODUCTION |
The bovine papillomavirus type 1 (BPV-1) E2 protein serves multiple functions for the virus. Binding of
its carboxy-terminal sequence-specific DNA binding domain (DBD) to
recognition elements in the papillomavirus genome regulates viral gene
expression and replication of the viral genome (1, 5, 8, 16, 19, 57). The amino-terminal activation domain (AD) of E2 mediates protein-protein interactions with the cellular transcription machinery. This region also binds the papillomavirus E1 protein, a DNA binding helicase essential for viral DNA replication (17, 27, 54). E2 targets E1 to the origin of replication. It is also believed that E2
plays an additional role in DNA replication, as several E2 mutants
retained E1 and DNA binding were unable to stimulate replication
(16). Because E2 is required for replication of viral
nucleosomal DNA but not naked plasmid DNA in vitro (33, 53),
it has been proposed that E2 may relieve chromatin suppression and
allowing entry of cellular replication and transcription factors to the
origin and promoter, respectively.
The cooperation of at least two functional units within the large
220-amino-acid E2 AD is essential for transcriptional activation. The
crystal structure of the human papillomavirus (HPV) E2 AD reveals
multiple surfaces available for protein-protein interactions (2,
25). A transcription factor IIB (TFIIB) interaction domain has
been mapped to residues 74 to 134 (56). Amino acids 134 to
216 mediate interaction with the activation domain modulation factor
AMF-1 (9). AMF-1 is identical to Gps2, which was initially reported as a human cDNA that repressed lethality of a G-protein mutation in Saccharomyces cerevisiae (46). Gps2
also interacts with the human T-cell leukemia virus type 1 (HTLV-1) Tax
protein (30). Gps2/AMF-1 has been shown to influence the
transcriptional activities of E2, Tax, and c-Jun (9, 30,
46). E2 mutants phenotypically selected for inability to bind to
AMF-1, while able to bind the E1 protein, exhibited defects in both
transcriptional activation and DNA replication (9). This
suggested that AMF-1 mediates a function required for both DNA
replication and transcriptional activation.
Given that the function of E2 in transcriptional activation and the
initiation of DNA replication involves formation of E2-dependent complexes on viral nucleosomal DNA, efficient assembly of these complexes in vivo might involve modification of nucleosome
structure. The coactivators p300/CREB binding protein (CBP) and
p300/CBP-associated cofactors (e.g., P/CAF, P/CIP-ACTR, and SRC-1)
contain an intrinsic histone acetyltransferase (HAT) activity (4,
11, 39, 47, 50, 55). Both p300 and CBP were demonstrated to
modify chromatin structures by acetylation of histones (12).
It is postulated that recruitment of coactivators bearing HAT activity
by promoter-bound transcription factors results in histone acetylation
of nearby nucleosomes, thus enhancing access of the transcriptional or
replication machinery to DNA (21, 36, 48). A class II
transactivator was shown to mediate interaction between a DNA-bound
factor (RFX5) and p300 (32, 43), suggesting that additional
pathways leading to recruitment of p300 by transcriptional activators
remain to be identified.
Recruitment of p300/CBP can also affect other aspects of transcription
carried out by RNA polymerase II (6, 12, 29, 44). p300 and
CBP function as coactivators by mediating protein-protein interactions
with the transcriptional apparatus (12, 44). Many cellular
transcription factors have been identified to interact with p300/CBP,
in a signal-dependent and sometimes mutually exclusive fashion
(18). p300/CBP can also directly acetylate TFIIE and TFIIF (29). The activities of p53, GATA-1, and human
immunodeficiency virus type 1 Tat proteins have been shown to be
regulated by p300/CBP acetylation (7, 22, 29, 31, 35, 40,
42). On the other hand, viral regulatory proteins target p300 and
CBP. The adenovirus E1A oncoprotein binds to p300 and inhibits both its transcriptional coactivator and HAT activity (10, 24, 38). Tax protein of HTLV-1 inhibits p300/CBP-mediated transcription by
interfering with recruitment of p300/CBP onto DNA (49, 51). Recently, HPV E6 proteins were shown to bind CBP at the same site as
E1A (58). While both low- and high-risk E6 proteins were shown to associate with p300, HPV type 16 (HPV-16) E6 interacted at
three sites, whereas HPV-6 E6 interacted only with the CH1 domain
(41).
Based on the genetic requirement for the AMF-1 interaction for E2
activity in transcription and DNA replication, a possible role for
AMF-1 in recruitment of p300 by the E2 AD was examined. We found that
AMF-1 enhances the interaction of p300 with E2 and that the complexes
were highly active for histone acetylation.
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MATERIALS AND METHODS |
Protein expression and purification.
For the production of
p53, BPV-1 E2, BPV-1 E1, AMF-1, and Flag-tagged p300, Sf9 cells were
grown to 80% confluence in 150-mm-diameter tissue culture dishes,
infected with recombinant baculoviruses expressing each of the
proteins, and incubated for 40 to 48 h. Cells were harvested,
washed with phosphate-buffered saline, and frozen at 
80°C. Cells
were extracted with lysis buffer (50 mM Tris [pH 8.0], 200 mM NaCl
[320 mM NaCl in the case of Flag-p300], 0.2% NP-40, 5% glycerol, 1 mM EDTA, 1 mM dithiothreitol [DTT], phenylmethylsulfonyl fluoride
[PMSF], leupeptin, pepstatin), and sonicated for 10 s followed
by 30 min on ice to resuspend and lyse the cells. Cell lysates were
clarified by centrifugation at 40,000 rpm for 20 min. Recombinant
baculovirus expressing AMF-1 was constructed by cotransfection of
insect cells with the nonviable viral DNA (Pharmingen) and a
complementing transfer vector containing AU1-tagged AMF-1
(pVL1392-AU1-AMF-1). The baculovirus strain expressing Flag-p300 is a
gift from Lou Schiltz and Yoshihiro Nakatani (39).
The glutathione S-transferase (GST)-p300 fusion proteins
and histidine-tagged p53 were synthesized in Escherichia
coli and purified as previously described (9). GST-p300
fusion expression vectors were kindly provided by Steven R. Grossman
and David M. Livingston. Induction of His6-AMF-1 expression
in S. cerevisiae was done as described previously
(9). Yeast cell pellets were resuspended in a mixture of 20 mM Tris (pH 8.0), 400 mM NaCl, 1% Tween 20, PMSF, leupeptin, and
pepstatin and lysed by the glass bead method. The yeast expression
vector for His6-AMF-1 (YEplac112G6His:AMF-1) was
constructed by cloning the His-AMF-1 open reading frame into YEplac112G
(9), placing the His6-AMF-1 fusion under control of the GAL promoter.
Transcriptional activation.
Transactivation assays with E2
were done essentially as described elsewhere (9). All
transfections included pSV
-gal, which was used to standardize E2
activation values for transfection efficiency. C33A cells were
transfected with 100 ng of E2 expression construct pCGE2B,
pcDNALexA-E2(1-216) (9), pCG16E2 (13), or
pcDNALexA-16E2(1-208) along with 0, 250, or 1,000 ng of pCMVE1A12S (52). These transfections included 500 ng of the
E2-dependent reporter pE2-4SVluc or LexA-dependent reporter pDBL8,
where appropriate (9). VP16 AD fusions to the LexA DBD
(pcDNALexAVP16; 100 ng) and the minimal E2 DBD (pCGVP16E2 125; 200 ng)
were used to demonstrate the specificity of E1A inhibition for E2. For
AMF-1 and p300 stimulation of E2-dependent transcription (Fig. 1), 500 ng of the E2-dependent reporter pE2-4SVluc was cotransfected into C33A
cells with or without 100 ng of E2 expression vector pCGE2B, 3 µg of
AMF-1 expression vector (9), and 0, 100, or 200 ng of p300
expression vector pCMVp300NHA (14). Backbone pCG vector was
added to each sample to bring the total amount of cytomegalovirus
promoter-containing DNA to 4 µg. At 48 h after transfection, the
luciferase activities in cell lysates were measured with the luciferase
assay system (Promega) and presented as the increase in activation over
reporter alone.
Protein interaction assays.
Human C33A cells stably
expressing His6-AMF-1 or His6--galactosidase
(-Gal) were established by transfection of C33A cells with
pcDNA3.1/6H:AMF-1 or pcDNA3.1/6H:LacZ DNA. Transfected cells were
maintained in medium containing G418 (300 µg/ml; GIBCO/BRL) for 2 weeks, and positive colonies were selected for expression of
His6-AMF-1 or His6--Gal by Western blotting.
Transient expression of hemagglutinin epitope-tagged p300 (HA-p300) in
C33A cells expressing His6-AMF-1 or
His6--Gal was accomplished by transfecting
HA-p300-expressing plasmid pCMVp300NHA and harvesting cells
48 h after transfection. For coprecipitation of HA-p300 with
His6-AMF-1 or His6--Gal, the cell extract
was adjusted to 40 mM imidazole. Nickel-nitrilotriacetic acid (Ni-NTA)
beads (Qiagen) were added in the presence or absence of 10 mM EDTA.
Binding was allowed to proceed for 2 h at 4°C. Bound proteins
were eluted with extraction buffer plus 250 mM imidazole. Concentrated
eluates were resolved by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) on a 6% gel and subjected to Western
blotting analysis using anti-p300 monoclonal antibody MAb RW128
(14, 15). For coimmunoprecipitation of AMF-1 with p300, cell
extract expressing His6-AMF-1 was incubated with anti-HA
MAb 12CA5 (Boehringer Mannheim) or anti-HPV-16 E6 ascites fluid. The
immunocomplexes were pulled down with protein A-Sepharose beads (PAS)
(Pharmacia) and washed with lysis buffer. Proteins were released from
PAS beads by boiling in SDS-PAGE sample buffer and Western blotted with
anti-AMF-1 serum.
For precipitation of proteins from Sf9 insect cell lysates, the cell
lysates were diluted 1:1 in a buffer containing 50 mM Tris (pH 8.0),
100 mM KCl, 0.1 mM EDTA, 2 mM DTT, 0.2% NP-40, 0.1% nonfat milk,
2.5% glycerol, PMSF (100 µg/ml), leupeptin (0.5 µg/ml), and
pepstatin A (1 µg/ml) before addition of antibody and PAS beads. The
reactions were incubated at 4°C for 3 h. Beads were collected
afterwards and washed three times in 1 ml of LSAB buffer (100 mM Tris
[pH 8], 100 mM NaCl, 1% NP-40, 2 mM DTT, 100 µg of PMSF per ml).
Proteins remained on beads were then analyzed by Western blotting using
the Super Signal Ultra chemiluminescent reagent (Pierce). GST pull-down
experiments were done as described elsewhere (9).
Acetylation analysis.
For histone acetylation assays,
immunopurified E2-p300 or AMF-1-p300 complexes were mixed with 500 ng
of histones (Sigma) in a 30-µl reaction buffer containing 50 mM Tris
(pH 8.0), 10% glycerol, 0.1 mM EDTA, 1 mM DTT, PMSF (100 µg/ml),
leupeptin (0.5 µg/ml), pepstatin A (1 µg/ml), 10 mM sodium
butyrate, and 0.3 µl of [14C]acetyl coenzyme A (100 µCi/ml, 1.54 nmol/µl) and incubated for 30 min at 30°C followed
by an additional 10 min on ice. Histone proteins were resolved by
SDS-PAGE on a 15% gel and quantitated with a Bio-Rad GS-250 molecular imager.
Acetylation of p53, AMF-1, E2, and E1 by p300 was analyzed both in vivo
and in vitro. In vivo analysis was carried out by coinfection of
Flag-p300-expressing baculovirus with one or more of the baculoviruses
expressing p53, AMF-1, E2, or E1 to Sf9 cells. At 24 h after
infection, 5 mM sodium butyrate and 5 µM trichostatin A were added
into culture medium. Cells were harvested at 40 h and lysed as
described for protein production in insect cells. Target proteins were
immunoprecipitated and Western blotted first with anti-acetyl-lysine
antibody (Upstate Biotechnology) and then with antibody against the
corresponding protein. Between the two blottings, the polyvinylidene
difluoride (PVDF) membranes were incubated at 55°C for 30 min in
Tris-buffered saline plus 0.1% Tween 20 (TBST) with 1% SDS and 50 mM
-mercaptoethanol, washed in TBST, and reblocked with 5% nonfat
milk. In vitro acetylation was carried out in a similar way except that
p300 and other target proteins were made separately in Sf9 cells, and
cell lysates were combined in vitro followed by a 30-min incubation at
30°C in the presence of 0.05 mM acetyl coenzyme A (Sigma) and 10 mM
sodium butyrate, before immunoprecipitation.
| |
RESULTS |
p300 and AMF-1 stimulate transcriptional activation by BPV-1
E2.
Previously we demonstrated that a novel cellular protein,
AMF-1, interacted with an 82-amino-acid subdomain of the BPV-1 E2 AD
(9). Mutations in this region that abolished E2 interaction with AMF-1 were found to be defective for transcriptional activation, suggesting that AMF-1 is a coactivator of E2-dependent transcription. It has been well established that p300 is a transcriptional coactivator (29, 34). To determine whether p300 is involved in the E2 transcription activation pathway, an E2-dependent luciferase reporter was transfected into human C33A cells with or without E2 and p300 expression vectors. As shown in Fig. 1,
exogenous expression of p300 stimulated transactivation by E2 ~ 2-fold. In other studies, p300 was found to enhance p53 transactivation
by a similar magnitude (3, 34). Notably, coexpression of
AMF-1 with p300 stimulated E2 transactivation approximately fourfold
(Fig. 1). Previously we showed that AMF-1 alone did not stimulate the
basal expression of this E2-dependent reporter construct
(9). The observations that AMF-1 and p300 stimulate E2
transactivation in an additive but not synergistic fashion indicated
that AMF-1 and p300 affect the same activation pathway. Overexpression
of p300 did not restore activity of two transcriptionally inactive E2
mutants (9, 56), E2:W99C and E2:W145R, which are unable to
bind TFIIB and AMF-1, respectively (data not shown).
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FIG. 1.
p300 and AMF-1 additively stimulate BPV-1 E2
transcriptional activation. An E2-dependent luciferase reporter was
cotransfected into C33A cells with or without vectors expressing BPV-1
E2, AMF-1, and p300 as indicated; 0, 100, or 200 ng of p300 expression
vector was used when the effect of p300 was evaluated. Two days after
transfection, luciferase activities were measured and are presented as
the increase in activation over reporter alone. Each sample was
analyzed in triplicate, and standard deviations are shown. The
experiments were repeated several times with similar results.
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Adenovirus E1A inhibits E2-activated transcription.
The
functional significance of p300 recruitment for E2 transactivation was
evaluated by determining whether activation by E2 is inhibited by the
adenovirus E1A 12S protein (10, 23, 45). The E1A protein
binds p300 and inhibits both its acetylase activity and coactivator
functions through recruitment of RNA polymerase II (see references
10, 24, and 38 and references therein). In transient expression assays, E1A substantially inhibited activation of an E2-dependent reporter by the BPV-1 E2 and HPV-16 E2
proteins (Fig. 2A) but did not
significantly affect activation by E2DBD-VP16AD, a fusion of the E2 DBD
domain to the VP16 AD (amino acids 410 to 490). We previously found
that AMF-1 does not interact with this VP16 AD fragment, and the
E2-VP16 fusion lacked the region of E2 that interacts with AMF-1
(9). It has been reported that the VP16 does not interact
directly with p300 (37). E1A mutations that are defective
for Rb binding showed partial inhibition of E2, as did an N-terminal
CR1 mutation that alters p300 association (data not shown). It has been
reported that another region of E1A also interacts with p300
(10), and thus partial repression may be due to residual
p300 association. These results suggested that p300 participates in E2
transactivation.
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FIG. 2.
Adenovirus E1A inhibits E2-activated transcription. (A)
The E2-dependent luciferase reporter was cotransfected into C33A cells
in the presence or absence of wild-type (BPV-1 or HPV-16) E2, or
E2DBD-VP16AD fusion, and E1A expression vectors. Luciferase activities
were measured 2 days after transfection and are presented as the
increase in activation over reporter alone; 250 and 1,000 ng of E1A
expression vector were used. (B) The E2 AD confers sensitivity to E1A
inhibition. Conditions were as for panel A except that the luciferase
reporter is LexA dependent, and transcriptional activators are fusions
of the LexA DBD to the BPV-1 E2 AD (left), HPV-16 E2 AD (middle), and
VP16 AD (right).
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We also performed E1A inhibition experiments using fusions of the BPV-1
and HPV-16 E2 ADs to the LexA DBD to confirm that the inhibition by E1A
did not require the E2 DBD. E1A inhibited transactivation of a LexA
operator reporter by the fusions LexA-BPV-1-E2AD(1-216) and
LexA-16E2AD(1-208) but had little effect on activation by a LexA-VP16AD
fusion protein (Fig. 2B). The specificity of E1A inhibition for the E2
AD implies that p300 recruitment functions independently of the E2 DBD.
Since the E2 AD functionally interacts with both AMF-1 and p300, we
then examined whether AMF-1 and p300 interact each other in vivo.
Coprecipitation of p300 with AMF-1 from C33A cells.
Human C33A
cervical carcinoma cells were modified to stably express
His6--Gal or His6-AMF-1 (Fig.
3A). As shown by quantitative Western
blotting, only the His6-AMF-1 species was detected in cells
transfected with His6-AMF-1, with the endogenous AMF-1
protein below the detection level of the assay (Fig. 3A, lane 3).
Endogenous AMF-1 could be easily detected in the same amount of extract
from the parental C33A cell line (lane 4) and in
His6--Gal-expressing C33A cells (data not shown). The
level of His6-AMF-1 in the transfected cells was similar to
the level of endogenous AMF-1 in the parental C33A cells, implying that
the AMF-1 level is finely modulated in vivo. Furthermore, BPV-1 E2
activated transcription of an E2-dependent reporter efficiently in
cells expressing His6-AMF-1 (data not shown), indicating
that the His6-AMF-1 protein is able to carry out the
function of endogenous AMF-1. For binding experiments, the
His6--Gal and His6-AMF-1 proteins were
quantitatively exhausted from cell extracts by chelating to a Ni-NTA
resin. After extensive washing, both His6--Gal and
His6-AMF-1 proteins could be eluted from the resin by
imidazole (data not shown).
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FIG. 3.
Coprecipitation of p300 with AMF-1. (A) Stable
expression of His6--Gal or His6-AMF-1 in
human C33A cells. Equal amounts of total cell protein extracts from
parental C33A (lanes 2 and 4), His6--Gal-expressing C33A
(lane 1), and His6-AMF-1-expressing C33A (lane 3) cells
were subjected to Western blotting with either MAb against -Gal
(Boehringer Mannheim) (lanes 1 and 2) or polyclonal rabbit sera against
AMF-1 (lanes 3 and 4). (B) Human C33A cells expressing
His6-AMF-1 were transfected with pCMV-HA:p300 or vector
alone; 48 h later, extracts were prepared and incubated with
Ni-NTA resin in the presence (lane 3) or absence (lanes 1 and 2) of 10 mM EDTA. After extensive washing, His6-AMF-1 was eluted and
concentrated. Copurification of p300 with His6-AMF-1 was
probed by Western blotting with MAb RW128 (14, 15). Both
endogenous (lane 1) and HA-tagged (lane 2) p300 copurified with
His6-AMF-1. (C) The same cell extracts as in panel B were
incubated with anti-HA (lanes 1 and 4) or anti-BPV-1 E6 (lanes 2 and 5, as negative controls) antiserum. Immunoprecipitates were resolved by
SDS-PAGE and Western blotted with anti-AMF-1 serum. Equal aliquots of
each extract were run in the gel as an indication of AMF-1 expression
(lanes 3 and 6).
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The stable expression cell lines were then transfected with a p300
expression vector. The His6-AMF-1 in the cell extract was bound to Ni-NTA resin, washed extensively, and eluted with imidazole as
shown in Fig. 3B. Both endogenous (lane 1) and HA-tagged p300 (lane 2)
were present in the eluate, indicating that p300 copurified with the
His6-AMF-1 protein. No p300 was detected when binding was
performed in the presence of 10 mM EDTA (lane 3), which blocks binding
of the His6 tag protein to the Ni-NTA resin
(26). Nonspecific binding of p300 to the Ni-NTA resin in the
absence of EDTA was ruled out by the use of p300-transfected cell
extract expressing His6--Gal. His6--Gal
was quantitatively recovered using the Ni-NTA resin, but p300 was not
detected in the eluate (data not shown).
The association of AMF-1 and p300 was confirmed in a reciprocal assay.
HA-tagged p300 was transfected into the C33A cell line that expressed
His6-AMF-1. His6-AMF-1 was coimmunoprecipitated with HA-p300 using the anti-HA MAb 12CA5 (Fig. 3C, lane 1, top gel).
His6-AMF-1 was not precipitated from the same extract using a control antibody (Fig. 3C, lane 2). His6-AMF-1 was also
not detected in control immunoprecipitation reactions using the HA antibody and control extracts prepared from His6-AMF-1
cells transfected with vector alone (Fig. 3C, lane 4, bottom gel).
These experiments demonstrated that AMF-1 and p300 exist in a complex
in vivo.
In vitro complex formation of AMF-1 and E2 with p300.
To
further explore the relationships between E2, AMF-1, and p300, we
produced these proteins in Sf9 cells using recombinant baculoviruses.
In these experiments, p300 had an amino-terminal Flag tag that allowed
its isolation from insect cell extracts using the anti-Flag MAb M2
conjugated to Sepharose beads. Cell extracts containing AMF-1, E2, or
E1 were combined with extract containing Flag-p300 (Fig. 4, lane
3). Immunoprecipitations with M2
antibody-coated beads consistently pulled down AMF-1 and E2, but not
BPV-1 E1, in complex with Flag-p300. Neither AMF-1 nor E2 was present
in M2 complexes from uninfected cell extract that did not contain
Flag-p300 (lane 2), indicating that the AMF-1-p300 and E2-p300
interactions are specific. Immunoprecipitation of p300 was more
efficient with AMF-1 than with E2 (Fig. 4). Typically, approximately
30% of input AMF-1 could be coimmunoprecipitated with p300, while only
5% of input E2 was pulled down with the same amount of Flag-p300 (Fig.
4). In experiments using bacterially produced GST-p300 fusion and E2
proteins, association of these proteins was marginally above background
levels (data not shown).
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FIG. 4.
In vitro complex formation of AMF-1 and E2 with p300.
Sf9 cells were infected by recombinant baculoviruses expressing each of
the proteins, harvested 48 h postinfection, and lysed as described
in Materials and Methods. Cell extract with (lane 3) or without (lane
2, from uninfected Sf9 cells) Flag-p300 was incubated with extract
containing AMF-1, E2, or E1. Flag-p300 was immunoprecipitated with
anti-Flag MAb M2 conjugated to Sepharose beads (Sigma). After washing,
the immunoprecipitates were analyzed by Western blotting with rabbit
polyclonal antibody against AMF-1 or E1 or MAb against E2. The heavy
chain of M2 (M2 HC) was detected by anti-mouse secondary antibody. Lane
1 shows 10% of input cell extracts containing AMF-1, E2, or E1.
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Histone acetylation by E2-p300 and AMF-1-p300 complexes.
E2
or AMF-1 complexes were collected from Sf9 cell lysates, using an
antibody against each protein. The activity of p300 in the complexes
was tested by a histone acetylation assay (Fig. 5). Both E2 and AMF-1
immunoprecipitations showed acetylase activity only when combined with
extracts containing p300 (lanes 3 and 7), not in the absence of p300
(lanes 1, 2, 5, and 6). Immunoprecipitations using antibodies against
AMF-1 resulted in more acetylase activity than immunoprecipitations
with antibody against E2 when incubated with equal amounts of
p300-containing cell extract (compare lanes 3 and 7). The presence of
AMF-1 in the immunoprecipitations with E2 and p300 increased the
acetylase activity about twofold (compare lanes 3 and 4), indicating
that AMF-1 enhanced the interaction between E2 and p300.
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FIG. 5.
Histone acetylation by AMF-1-p300 and E2-p300
complexes. Immunoprecipitation reactions were set up with or without
Sf9 cell extracts containing p300, E2, or AMF-1, as indicated. A minus
sign represents equal amount of extract from uninfected Sf9 cells.
Protein complexes were immunoprecipitated with either MAb against E2 or
polyclonal antibody against AMF-1. Precipitates were washed and added
to histone acetylation reactions as described in Materials and Methods.
Histone proteins were resolved on an SDS-15% polyacrylamide gel and
analyzed with a Bio-Rad molecular imager.
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AMF-1 interacts with the N-terminal portion of p300.
In vitro
binding assays using GST-p300 fusions expressed in E. coli
and recombinant His6-AMF-1 purified from S. cerevisiae were performed to determine if p300 and AMF-1
interacted directly and to identify the domain on p300 that binds
AMF-1. In a GST pull-down assay, about 10% of the input
His6-AMF-1 was bound to GST-p300(1-595), while none was
retained by GST alone or GST-p300(744-1571), GST-p300(1572-2414) (Fig.
6A). Amino acids 1 to 595 of p300 include the CH1 domain that binds p53 (20). To determine whether
AMF-1 and p53 bind to the same region of p300, interaction between
His-AMF-1 and the CH1 domain of p300 [GST-p300(300-528)] was
examined. The results showed that AMF-1 binding to the CH1 domain was
weak, with only 1.9% of input bound (Fig. 6B). A larger fusion
[GST-p300(162-567)] bound AMF-1 more efficiently, retaining 8.4% of
input (Fig. 6B). As expected, the two fusion proteins bound to p53 with
similar efficiencies [GST-p300(300-528), 31% input;
GST-p300(162-567), 38% input] (Fig. 6B). These results indicated that
the requirements for AMF-1 and p53 binding to the N terminus of p300
are not identical. A similar situation was observed when mdm2 and p53
binding to this region of p300 was examined. While mdm2 bound
essentially to the CH1 domain, p53 binding to CH1 required additional
residues (20).
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|
FIG. 6.
Direct interaction of AMF-1 with p300. GST or GST-p300
fusions were incubated with His-AMF-1 or His-p53 and washed
extensively. Bound proteins were resolved by SDS-PAGE followed by
Western blotting. (A) AMF-1 binds to the amino-terminal 595 amino acids
of p300 but not GST alone or GST-p300 fusions containing amino acid
residues 744 to 1571 and 1572 to 2414. (B) Comparison of p300 CH1
domain (amino acids 300 to 528) binding by AMF-1 and p53.
|
|
Acetylation analysis of AMF-1, E2, and E1 by p300.
The
preceding results suggested that histones are a potential target for
acetylation by the p300 complexes with AMF-1 and E2. To determine
whether AMF-1 or E2 can also be acetylated by p300, Sf9 cell lysates
containing each of p53, AMF-1, E2, and E1 were mixed with cell lysates
containing p300 in the presence of acetyl coenzyme A and deacetylase
inhibitors. After 30 min of incubation at 30°C, target proteins (p53,
AMF-1, E2, and E1) were immunoprecipitated and analyzed for the
presence of acetyl-lysine by Western blotting. Neither AMF-1, E2, nor
E1 reacted with acetyl-lysine antibodies, while p53 showed strong
acetyl-lysine reactivity after incubation with p300 (Fig.
7). To examine the effect of E2 on acetylation of AMF-1, cell lysate containing E2 was added into the
reaction when acetylation of AMF-1 was tested; vice versa, AMF-1 was
added into E2 acetylation reaction to test its effect on E2
acetylation. The combination of E2 with AMF-1 and p300 did not lead to
their acetylation on lysine (Fig. 7). Similarly, E2 had no effect on
acetylation of E1 (Fig. 7). The acetylation was also performed in vivo
by coinfection of Sf9 cells with recombinant baculovirus expressing
p300 and one or more baculoviruses expressing p53, AMF-1, E2, and E1.
Target proteins (p53, AMF-1, E2, and E1) were immunoprecipitated
directly from cell lysates and tested for acetyl-lysine by Western
blotting. The results were similar to those of in vitro assays (data
not shown). These data indicated that AMF-1, E2, and E1 are probably
not targets of p300 lysine acetylase activity.
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|
FIG. 7.
Acetylation analysis of p53, AMF-1, E2, and E1 by p300.
In vitro acetylation of p53, AMF-1, E2, and E1 was tested using Sf9
cell extracts containing each of these proteins and extract containing
p300. Cell extract containing p300 was mixed with lysate containing
each of p53, AMF-1, E2, and E1 at 30°C for 30 min, in the presence of
0.05 mM acetyl coenzyme A and 10 mM sodium butyrate. p53, AMF-1, E2,
and E1 were then immunoprecipitated (IP) by incubation with antibodies
(Ab) against each protein. Immunoprecipitates were washed, resolved on
an SDS-10% polyacrylamide gel, and transferred to PVDF membranes.
After Western blotting with antibody against acetyl-lysine, the PVDF
membranes were stripped and Western blotted with antibody against p53,
AMF-1, E2, or E1. In each panel, results of anti-acetyl-lysine blotting
are shown at the top. Acetylation reactions were also performed by
mixing AMF-1, E2, and E1 cell extracts. In vivo acetylation assays were
carried out by coinfecting Sf9 cells with baculovirus expressing p300
and one or more baculoviruses expressing p53, AMF-1, E2, or E1, as
indicated; 24 h after infection, 5 mM sodium butyrate and 5 µM
trichostatin A were added to the cell culture medium. Cell extracts
were prepared 48 h postinfection. p53, AMF-1, E2, and E1 proteins
were immunoprecipitated from 200 µl of cell extracts, followed by the
same Western blotting procedure as for in vitro assays.
|
|
| |
DISCUSSION |
We previously identified AMF-1/Gps2 as an E2-interacting factor by
a yeast two-hybrid screen. AMF-1 binds the E2 AD and increases its
transcriptional activity. E2 mutants that were unable to bind AMF-1
were severely crippled for activation of transcription and replication.
We questioned whether AMF-1 affected a putative common step such as
chromatin remodeling, and by analogy with other transcriptional activators, we suspected that E2 might interact with p300. While we
observed only weak interactions between E2 and p300, direct complex
formation between the AMF-1 and p300 proteins was more efficient (Fig.
4). We attempted to show complex formation between the endogenous AMF-1
and p300 in different cell lines, but those experiments were not
successful (data not shown). It is possible that the endogenous AMF-1
bound to p300 is below detectable amounts; AMF-1-p300 complex
formation may also be transient or result in a complex inaccessible to antibodies.
AMF-1 enhanced the interaction of E2 with p300, and overexpression of
both AMF-1 and p300 showed additive stimulation of E2-dependent transcription (Fig. 1). Overexpression of p300 did not increase the transcriptional activity of E2: W145R, a mutant that is
defective for AMF-1 binding (data not shown). The sensitivity of BPV-1
E2 transactivation to inhibition by adenovirus E1A and stimulation of
E2 activation by expression of exogenous p300 imply that p300 recruitment plays a role in transcriptional activation by E2. The
recruitment of p300 in this fashion is likely a general property of
papillomavirus E2 proteins, because residues of the BPV-1 E2 AD
critical for AMF-1 interaction are highly conserved in other E2
proteins (9). We also demonstrated direct interaction of AMF-1 with HPV E2 proteins using GST pull-down and mammalian two-hybrid assays (unpublished data).
The AMF-1 interaction has been mapped to residues 162 to 567 of p300
(Fig. 6). This region of p300 also participates in both direct and
mdm2-mediated interactions with p53 (20) and plays an
important role in regulating turnover of p53 (20). A
GST-p300 fusion protein [GST:p300(300-528)] containing the CH1 region
bound p53 with high avidity but interacted weakly with AMF-1,
indicating that AMF-1 and p53 interaction domains on p300 are not
identical (Fig. 6). While the CH1 domain may play a role in AMF-1-p300
interaction, additional residues appear to be required for efficient
binding. These results suggest that AMF-1 may regulate p53 through
p300. We have observed that AMF-1 significantly stimulates the activity of p53 (unpublished data).
The dual nature of the p53-p300 interaction prompted us to search for
direct interaction of BPV-1 E2 with p300. Our initial attempts to
detect E2-p300 complexes in extracts prepared from p300- and
E2-transfected C33A cells failed, suggesting that direct E2-p300
interaction is not sufficient for p300 recruitment (data not shown).
However, weak binding of E2 to p300 could be detected using recombinant
E2 and p300 proteins produced in insect cells (Fig. 4). We cannot
exclude the possibility that E2 protein association with Flag-p300 is
indirect. Histone acetylation experiments also showed that antibody
against E2 could immunoprecipitate acetylase activity from cell extract
containing both E2 and p300 proteins but not from cell extract
containing E2 or p300 alone (Fig. 5). We hypothesize that AMF-1 binds
p300 and enhances its normally weak interaction with E2. Currently we
are screening our E2 mutations for the ability to bind recombinant p300
and testing whether these overlap with the AMF-1 binding domain.
Genetic evidence indicates that recruitment of RNA polymerase II by the
interaction of AMF-1 with p300 would be necessary but not sufficient
for transcriptional activation by E2. For example, a TFIIB binding
domain has been mapped to a region of the E2 AD distinct from the AMF-1
binding domain, and TFIIB binding-defective mutants within this domain
were identified (56). These TFIIB binding-defective mutants
were unable to activate transcription but retained the ability to
associate with AMF-1, suggesting that TFIIB binding, as well as AMF-1
binding, is necessary for transcriptional activation (unpublished
data). Nakajima et al. also found a dual requirement for CREB:
activation of transcription requires both recruitment of the RNA
polymerase II through interactions of the CREB KIX domain with CBP and
recruitment of TFIID by the glutamine-rich Q2 domain of CREB by
interaction with human TAFII 130 (38). These authors also
found that CREB activation and recruitment of RNA polymerase II by CBP
was inhibited by E1A. The inhibition of RNA polymerase II recruitment
by p300/CBP might also explain the sensitivity of E2 transactivation to E1A.
E1A has been recently found to inhibit the acetyltransferase activity
of p300/CBP as well as recruitment of RNA polymerase II (10,
24). Recruitment of histone acetylase activity (4, 39)
by AMF-1 could result in modification of the chromatin structure and
promote formation of transcription and replication initiation complexes. Although we could not find any report showing that the HAT
activity of p300/CBP is required for DNA replication, it was recently
demonstrated that histone acetyltransferase HBO1 interacts with the
ORC1 subunit of the human DNA replication initiator protein
(28). E2 targets the papillomavirus E1 DNA helicase to the
origin of replication, which contains E2 binding sites. The phenotype
of the AMF-1 binding-defective mutants (9) is consistent
with a defect in the recruitment of histone acetylase activity that
results in an inability to modulate chromatin remodeling. It will be of
interest to see if p300 and CBP are directly involved in papillomavirus
DNA replication.
Our results showed that fusions of the BPV-1 and HPV-16 E2 ADs to the
LexA DBD retain sensitivity to inhibition by E1A (Fig. 2), suggesting
that the mechanism by which p300 influences E2 transcriptional
activation is independent of the E2 DBD. Acetylation of p53 and GATA-1
by p300/CBP has been found to modulate the function of these
transcription factors at the level of DNA binding (22, 35,
42). The DNA binding activity of p53 is regulated in vivo via
acetylation by p300/CBP and P/CAF in response to DNA damage (42). Acetylation of human immunodeficiency virus type 1 Tat by p300 or P/CAF at two lysine residues (Lys50 and Lys28) regulates its
activities in transcription, binding to an RNA polymerase II C-terminal
domain (CTD) kinase and release from trans-activation response region (TAR) RNA (31). It is unlikely that p300
regulates the E2 DNA binding domain in an analogous manner, as we
showed that p300 stimulated the chimera of the E2 AD to the LexA DBD. Furthermore, acetylation experiments with antibody against
acetyl-lysine failed to show acetylation of AMF-1, E2, and E1 by p300
(Fig. 7). However, we cannot exclude the possibility that these
proteins are acetylated, perhaps on another amino acid, in vivo.
Further experiments are necessary to find out what properties of E2 may be affected upon binding to p300 and AMF-1.
| |
ACKNOWLEDGMENTS |
Y.-C. Peng and D. E. Breiding contributed equally to the work.
We are grateful to L. Banks, M. Botchan, S. Grossman, D. Livingston, Y. Nakatani, and L. Schiltz for providing reagents. We thank the members
of the lab for many useful discussions.
This work is supported by NIH grants R01 CA58376 and U01 AI38001 to
E.J.A.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Dermatology, New England Medical Center, Box 166, 750 Washington St., Boston, MA 02111. Phone: (617) 636-1493. Fax: (617) 636-6190. E-mail: eandroph{at}opal.tufts.edu.
| |
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Journal of Virology, July 2000, p. 5872-5879, Vol. 74, No. 13
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
