| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
J. Biol. Chem., Vol. 275, Issue 27, 20436-20443, July 7, 2000
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
From the
Received for publication, January 10, 2000, and in revised form, March 24, 2000
p53, the most commonly mutated gene in cancer
cells, directs cell cycle arrest or induces programmed cell death
(apoptosis) in response to stress. It has been demonstrated that p53
activity is up-regulated in part by posttranslational acetylation. In
agreement with these observations, here we show that mammalian histone
deacetylase (HDAC)-1, -2, and -3 are all capable of down-regulating p53
function. Down-regulation of p53 activity by HDACs is HDAC
dosage-dependent, requires the deacetylase activity of
HDACs, and depends on the region of p53 that is acetylated by
p300/CREB-binding protein (CBP). These results suggest that
interactions of p53 and HDACs likely result in p53 deacetylation,
thereby reducing its transcriptional activity. In support of this idea,
GST pull-down and immunoprecipitation assays show that p53 interacts
with HDAC1 both in vitro and in vivo.
Furthermore, a pre-acetylated p53 peptide was significantly deacetylated by immunoprecipitated wild type HDAC1 but not deacetylase mutant. Also, co-expression of HDAC1 greatly reduced the in
vivo acetylation level of p53. Finally, we report that the
activation potential of p53 on the BAX promoter, a natural
p53-responsive system, is reduced in the presence of HDACs. Taken
together, our findings indicate that deacetylation of p53 by histone
deacetylases is likely to be part of the mechanisms that control the
physiological activity of p53.
p53, a critical regulator of cell proliferation, transmits signals
to genes that control the cell cycle and apoptosis (or programmed cell
death) when cells are under stress (1-2). These functions are
principally controlled by the ability of p53 to bind to DNA with
sequence specificity and activate transcription. Inactivation of this
property of p53, mostly by mutations that occurred in the central
DNA-binding domain, often leads to malignancy. Several distinct
functional domains within p53 have been characterized (3) as follows:
an N-terminal domain that harbors transactivation activity (amino acids
1-43), a central DNA-binding domain that recognizes specific DNA
sequences (amino acids 100-300), and the C-terminal region that
includes a tetramerization domain (amino acids 320-360) as well as a
regulatory domain (amino acids 363-393). Posttranslational
modifications of the extreme C-terminal 30 residues have been shown to
play a very important role in the regulation of p53-specific DNA
binding. For example, phosphorylation, antibody binding, deletion, or
recently identified acetylation of this region can convert p53 from a
latent to an active form for DNA binding. A model for allosteric
regulation of p53 was proposed in which the sequence-specific DNA
binding activity of p53 is negatively regulated by its inhibitory
C-terminal domain. Upon exposure to stress, posttranslational
modifications described above relieve this inhibition (4).
Recruitment of p300/CBP,1 a
co-activator with putative histone acetyltransferase activity (5-6),
by p53 is believed to result in the synergistic enhancement of p53
transactivation activity by at least two different pathways, core
histone acetylation and p53 acetylation. Hyperacetylation of histones
correlates with enhanced transcription, presumably by increasing the
accessibility of transcription factors to nucleosomal DNA (7). However,
core histone acetylation alone does not necessarily account for maximal activation, suggesting the possibility of alternative mechanisms. Posttranslational acetylation of p53 at its C-terminal domain has been
demonstrated in several independent studies (4, 8, 9). Distinct lysines
within p53 were found to be acetylated by p300/CBP (Lys-373 and
Lys-382) and PCAF (p300/CBP
associated factor) (Lys-320) both in
vitro and in vivo. Acetylation of p53 greatly enhances
its sequence-specific DNA binding activity and is induced in response
to DNA damage (4, 8, 9). In addition to p53, a growing number of
non-histone transcription factors were found to be acetylated by
histone acetyltransferases. These include general transcription factors
TFIIE Histone deacetylases are active components of transcriptional
corepressor complexes (19-20). At least five yeast and six human HDAC
enzymes exist. In higher eukaryotes, HDAC1 was first purified using an
affinity matrix based on the deacetylase inhibitor trapoxin (21). At
the same time, mouse and human HDAC2 was identified based on a yeast
two-hybrid screening using YY1 transcription factor as bait (22). YY1
negatively regulates transcription by tethering HDAC2 to DNA as a
corepressor. Both HDAC1 and HDAC2 associate stably with mSin3A in
mediating transcriptional repression. This HDAC-mSin3 complex can be
recruited to specific promoters via interactions with a growing number
of sequence-specific transcription factors (19-20). These include
unliganded nuclear hormone receptors (e.g. RAR and TR),
Mad/Max and Mxi/Max heterodimer (23), MeCP2 (24), and p53 (25). As well
as being associated with mSin3A, HDAC1/2 are components of the NuRD
(nucleosome-remodeling histone deacetylase) complex which has been implicated a role in
transcriptional repression by DNA methylation (26-27). Mammalian HDAC3
was cloned by the searches of EST data bases (28-29) and found to
repress YY1-mediated transcriptional repression via direct interactions with YY1 (28). Searches of EST data bases led to the discovery of three
more histone deacetylases HDAC4, HDAC5, and HDAC6 (30-33). Sequence
alignment analysis reveals that the mammalian HDACs identified so far
fall into two groups, the yeast RPD3 protein-like (HDAC1, -2, and -3)
and the yeast HDA1 protein-like (HDAC4, -5, and -6) (21, 30, 33). It is
becoming evident that each group of HDACs is utilized by distinct sets
of transcriptional repressors (20).
Whether HDACs play a role in regulating p53 function remains
unaddressed. In the discovery of HIV Tat acetylation (16), treatment of
cells with histone deacetylase inhibitor TSA (34) was found to
synergistically work with Tat in activating HIV-1 promoter, presumably
through inhibiting the deacetylation of Tat. Furthermore, it was found
that the retinoblastoma (Rb)-associated histone deacetylase could
deacetylate E2F1 (18). These studies raise the possibility that,
similar to Tat and E2F1, modification of p53 by HDACs might play a
direct role in regulating p53 function. In support of this hypothesis,
in the course of studying the transcriptional repression function of
p53 in apoptosis, Murphy et al. (25) found p53 recruited
HDACs, via interactions with mSin3A, to repress two genes,
Map4 and stathmin. The underlying mechanism at
least involves core histone deacetylation. However, the possibility of
p53 deacetylation has not been examined. In the present study, we
report that mammalian HDAC1, -2, and -3 specifically down-regulate the
transactivation activity of p53. The inhibition is HDAC
dosage-dependent and requires the deacetylase activity of
HDACs. Most importantly, the down-regulation of p53 function by HDACs
relies largely on the C-terminal 30 residues of p53, the region
containing the basic lysines (Lys-373 and Lys-382) that have been shown
to be acetylated by p300/CBP in vivo (4, 8, 9). These
results of functional assays are further supported by the fact that
HDACs form a complex with p53 and significantly deacetylate p53 both
in vitro and in vivo. Finally, we show that HDACs
inhibit the activity of BAX promoter, a nature system responsive to
p53, in a p53-dependent manner. Our findings strongly
suggest that HDAC1, -2, and -3 participate in p53-mediated gene
regulation, at least in part by directly deacetylating p53.
Plasmids--
The following plasmids have been described
previously: pSVp53V143A and pSVp53V143ACD30, both of which express
temperature-sensitive derivatives of p53V143A (35), the p53 reporter
construct p3PREcCAT (35); pME18S-FLAG-HDAC2, which expresses FLAG
epitope-tagged HDAC2 (36); pCMV-FLAG-HDAC3, which expresses FLAG
epitope-tagged HDAC3 (28); pFLAG-HDAC1(H199F) and pFLAG-HDAC1(H141A),
both of which express FLAG epitope-tagged mutant HDAC1 defective in deacetylase activity (37); pSGVP, which expresses GAL4VP16, and
pG5E1BCAT (38); pGST-HDAC1, pGST-HDAC2, and pGST-HDAC3 (28); pBAX-Luc
(39).
To construct plasmid pcDNA3-HDAC1-FLAG, which encodes a C-terminal
FLAG epitope-tagged HDAC1, the BamHI fragment from
pBJ5-HD1-F (21) was subcloned into the BamHI site of
pcDNA3 (Invitrogen). Plasmid pME18S-FLAG-HDAC2-(1-372), which
encodes FLAG epitope-tagged mutant HDAC2 defective in deacetylase
activity, was created by digestion of plasmid pGEM7Zf-mRPD3 (22) with
SnaBI and BamHI, followed by fill-in and
self-ligation. A further digestion of the resulting plasmid with
EcoRI and BglII was performed followed by
subcloning of the cut out fragment into pME18S-FLAG (40). Plasmid
pME18S-HDAC3-(1-180), which encodes FLAG epitope-tagged mutant HDAC3
defective in deacetylase activity, was constructed by digestion of the
plasmid pBS-SK-HDAC3-(1-428) with HindIII. The cut out
fragment was subsequently cloned into pME18S-FLAG vector (40) between
EcoRI and XhoI sites. pGEM3-p53 was created by
subcloning of the cDNA corresponding to p53 sequence into pGEM3 vector (Promega) between HindIII and BamHI sites.
Cell Culture, Transfection, Chloramphenicol Acetyltransferase
(CAT) Assay, and Luciferase Assay--
The human lung carcinoma cells
H1299 and the human osteosarcoma cells Saos-2 were maintained in
Dulbecco's modified Eagle's medium with 10% fetal calf serum.
Approximately 2.5 × 105 cells (H1299) or 7.5 × 105 cells (Saos-2) were seeded in each 60-mm culture dish
18-24 h before transfection. Calcium phosphate-mediated DNA
transfection was performed as described previously with some
modifications (41). Typically, transfection lasted 18 h. CAT
activity was measured 72 h after transfection and quantified as
described previously (41). For temperature shift assays, the incubation
temperature was switched to 30 °C for 24 h after incubation at
37 °C for 48 h. For luciferase assays, cell culture and DNA
transfection were done as described above except that 0.5 µg of
pBAX-Luc, 0.1 µg of pRL-TK, 0.5 µg of pSVp53V143A, and 2.5 µg of
plasmids encoding HDACs were introduced into cells. After harvesting
the cells, the luciferase activity was determined using the Dual
Luciferase Reporter Assay System (Promega).
Western Immunoblotting--
An equal amount (approximately 10 µg) of proteins from extracts of transfected cells was boiled in a
sample buffer (125 mM Tris-HCl, pH 6.8, 100 mM
dithiothreitol, 2% SDS, 20% glycerol, 0.005% bromphenol blue) for 5 min and then loaded onto a 12% SDS-polyacrylamide gel. After
electrophoresis, proteins were transferred to an Immobilon membrane
(Millipore). p53, FLAG-HDAC derivatives were detected with antibodies
directed against p53 (Ab-6, Oncogene) and FLAG epitope (Sigma),
respectively, using the ECL system (Amersham Pharmacia Biotech)
according to the manufacturer's instructions.
In Vitro Translation of Proteins--
In vitro
transcription/translation was performed with the TNT system (Promega)
according to the manufacturer's instructions. The template was
pGEM3-p53.
GST Fusion Proteins and Pull-down Assay--
GST, GST-p53,
GST-HDAC1, GST-HDAC2, and GST-HDAC3 were expressed in and purified from
Escherichia coli BL21DE3pLysS strain according to standard
protocols (42-44). The ligand concentrations, using bovine serum
albumin as a standard, were 14 mg/ml GST beads and 0.3 mg/ml each of
GST-HDAC1, GST-HDAC2, and GST-HDAC3 beads. Aliquots (50 µl, ~15
µg of proteins on beads) of the GST, GST-HDAC1, GST-HDAC2, and
GST-HDAC3 beads were incubated overnight at 4 °C with in
vitro translated, [35S]methionine-labeled p53. After
being washed with buffer D (45), bound proteins were eluted from beads
with buffer D containing 0.1 M glutathione and analyzed by
electrophoresis on a 10% SDS-polyacrylamide gel.
Immunoprecipitation--
Approximately 5 × 105
cells were seeded in each 100-mm culture dish 18-24 h before
transfection. Cell cultures and DNA transfections were performed as
described above. Briefly, 20 µg each of the corresponding plasmids
was transfected into H1299 cells. Cell extracts were prepared by lysis
in Nonidet P-40 buffer (20 mM Tris-HCl, pH 7.2, 100 mM NaCl, 10% glycerol, 0.1% Nonidet P-40, 1 mM EDTA) containing 1× protease inhibitor mixture
(CompleteTM, Roche Molecular Biochemicals). Equal amounts
of lysates were incubated with antiserum (1:100 dilution) overnight at
4 °C, followed by 2 h precipitation with protein A/G-agarose
beads (Calbiochem). All immunoprecipitates were washed three times with
Nonidet P-40 buffer. Bound proteins were eluted from the affinity
matrix in SDS loading buffer and separated by SDS-polyacrylamide gel
electrophoresis, followed by Western blotting analysis described above.
Primary antibodies for Western were anti-FLAG (Sigma) at 1:400
dilution, anti-p53 (Ab-6, Calbiochem) at 1:2000 dilution, anti-Ace p53
(Lys-373 and Lys-382) (Upstate Biotechnology Inc.) at 1:500 dilution.
Chemical Acetylation of Peptide--
Peptides corresponding to
the C-terminal 26 amino acids of p53 (residues 364-389,
5'-AHSSHLKSKKGQSTSRHKKLMFKTEG-3') or the N-terminal fragment of histone
H4 (5'-SGRGKGGKGLGKGGAKRHRKVLR-3') were synthesized by the core
facility center of the Institute of Zoology, Academia Sinica, and
purified to 95% purity by high pressure liquid chromatography. To
acetylate the peptides, 0.4 mg of peptides were incubated with 0.5 ml
of [3H]CH3COONa (NEN Life Science Products,
catalog number NET-003H, 5 mCi (185 Mbq), 2-5 Ci (74.0-185 Gbq)/mmol
in ethanol) and 10 µl of BOP (BOP solution is always prepared
freshly. For 100 µl of BOP solution, take 0.01 g of BOP (Aldrich
catalog number 22,608-4) into 97 µl of acetonitrile (Aldrich catalog
number 27,071-7) at room temperature overnight with stirring. After
mixing well to dissolve, 3 µl of triethylamine (Aldrich catalog
number 13,206-3) was added and mixed thoroughly. The final
concentration for BOP and triethylamine were 0.24 M and 0.2 M, respectively. This labeling was processed in the
chemical hood. To purify the radiolabeled peptides, the Microcon-SCX
(Millipore catalog number 42460) was prewashed with 500 µl of 10 mM HCl in methanol once and then with 500 µl of 10 mM HCl, 10 mM methanol in double distilled
water. An aliquot (250 µl) of the labeling mixture was loaded onto
the prewashed Microcon-SCX column and then spun at 1200 × g for 1 min. The column was then washed twice with 500 µl
of 10 mM HCl in 10% methanol, followed by centrifugation
at 1200 × g for 1 min. To elute the sample, 50 µl of
3 N HCl in 50% isopropyl alcohol was added to the reversed
column, followed by centrifugation at 14,000 × g for
15 s. Finally, the elute was dried out and dissolved into 500 µl
of double distilled water and stored at Peptide Deacetylase Assay--
H1299 cells were maintained in
Dulbecco's modified Eagle's medium with 10% fetal bovine serum. For
transfection, 5 × 106 cells were seeded in a 100-mm
culture dish for 16 h. Twenty µg of pcDNA3-HDAC1-FLAG was
introduced into cells with the calcium phosphate coprecipitation method
as described (41). 72 h after transfections, cells were harvested,
lysed in Jurkat lysis buffer (37). Immunoprecipitation of the HDAC1
immunocomplex with FLAG antibodies (Sigma) was performed as described
(37). The precipitated HDAC1 complex was stored in 150 µl of ice-cold
HD buffer (20 mM Tris, pH 8.0, 150 mM NaCl,
10% glycerol) and subsequently used in the deacetylase reactions as
described with some modifications (28). Briefly, 20,000 cpm of purified
peptides were incubated with immunoprecipitates in 150 µl of ice-cold
HD buffer at room temperature overnight with mild shaking. To stop the
reactions, 50 µl of STOP solution (0.16 M acetic acid,
1.0 M HCl) was added into each reaction and mixed well by
vortexing. The released [3H]acetate was extracted by
adding 600 µl of ethyl acetate. 250 µl of upper layer was mixed
with 5 ml of scintillation mixture to detect the HD activity.
Dosage-dependent Inhibition of p53 Function by HDAC1,
-2, and -3--
Regulation of p53 function by posttranslational
acetylation has been demonstrated by several laboratories (4, 8, 9). A
recent finding by Murphy et al. (25) further indicates that p53 utilizes HDACs, basically through histone deacetylation, to repress
the transcription of two genes, Map4 and
stathmin. However, question as to whether deacetylation of
p53 itself plays a role has not yet been addressed. To assess the
possibility of HDACs in regulating p53 function, a CAT reporter
construct p3PREcCAT (35) containing three
p53-responsive elements (PRE) (46)
was transiently transfected into cells, in the absence or presence of
expression plasmids encoding p53 or HDACs. Since p53 has been shown to
inhibit the activities of promoters lacking PREs, we took advantage of
the temperature-sensitive p53 mutant p53V143A (35) to ensure optimal
expression of HDACs. In this way, HDACs were expressed first, and the
function of wild type p53 was then induced by a shift of the assaying
temperature from 37 to 30 °C. Two p53-deficient cell lines were used
throughout the study, the human lung carcinoma cells H1299 and the
human osteosarcoma cells SaoS-2 (data not shown). Similar results were
obtained. As shown in Fig. 1, p53 alone
strongly activated the p3PREcCAT reporter (lanes 2, 10, and
18). In the presence of increasing amounts of HDAC1
(upper panel, lanes 3-8), HDAC2 (middle panel, lanes
11-16), or HDAC3 (lower panel, lanes 19-24), the CAT
activity driven by p53 was decreased in a HDAC
dosage-dependent manner, suggesting a direct inhibition of
p53 function by HDACs.
Recruitment of HDACs by sequence-specific DNA-binding proteins has been
reported to repress transcriptional activity of many promoters in
vivo (19). To eliminate the possibility that overexpression of
HDACs affects the protein level of p53, thus resulting in the apparent
loss of p53 function, similar experiments were applied, followed by a
Western blot probed with antibodies directed against p53. As shown in
Fig. 2A, co-expression of
HDACs led to a dramatic decrease in the CAT activity driven by p53
(upper panel, compare lanes 3-5 to lane
2), consistent with the previous observation described in Fig. 1.
However, co-expression of HDACs did not affect the protein level of p53
to a significant extent (lower panel, compare lanes
3-5 to lane 2). Since acetylation of p53 by p300 greatly enhances its DNA-binding ability (4), and hence the transactivation activity (47), it is very likely that the observed loss
of p53 transactivation activity is due to direct deacetylation of p53
by HDACs. This possibility was explored in the following experiments.
HDAC Down-regulation of p53 Function Requires the Deacetylase
Activity of HDACs--
The specificity of HDAC inhibition of
p53-dependent transactivation was further examined. First,
we asked whether the deacetylase activity of HDACs was required to
repress p53 function. Several residues within the central regions of
the HDACs have been found to be essential for its deacetylase activity
(37, 48). To demonstrate that p53 down-regulation by HDACs depends on
the deacetylation event, wild type p53 was induced in the absence or
presence of FLAG epitope-tagged mutant HDACs (FLAG-mHDACs)
defective in the deacetylase activity. These mutants were constructed
by either site-directed mutagenesis (H199F) in HDAC1 (37) or deletion of the conserved deacetylase motif in the cases of HDAC2 and HDAC3 (see
"Materials and Methods"). As shown in Fig. 2B,
repression of p53 activity was greatly alleviated in the presence of
mutant HDACs (compare lanes 3-5 in Fig. 2B, upper
panel, to lanes 3-5 in Fig. 2A, upper
panel). Both wild type and mutant HDACs expressed to similar
levels, as detected in the Western blot probed with FLAG antibodies
(Fig. 2B, lower panel and data not shown). It should be noted that mutant HDAC1 (H199F) fails to interact with the
mSin3A protein (37). mSin3A is a transcriptional corepressor that
bridges HDAC function to sequence-specific DNA-binding proteins (23).
To exclude the possibility that the restoration of p53 function in the
presence of the deacetylase mutant HDAC1(H199F) was due to the loss of
the mediator protein, but not the loss of deacetylase activity, we
examined the effect of another deacetylase mutant HDAC1(H141A) (37),
which still associates with mSin3A, on repressing p53 activity. Similar
results were obtained (data not shown). These experiments indicate that
the deacetylase activity is indeed essential for HDACs to repress p53 function.
Down-regulation of p53 Function by HDACs Is Dependent on the
C-terminal Domain of p53, Which Contains the Acetylation Sites for
p300/CBP--
We next determined the p53 domain(s) involved in the
down-regulation by HDACs. As shown in Fig. 2C, deletion of
the C-terminal 30 residues of p53 (p53V143ACD30) did not
affect its transactivation activity (lane 2). However, the
HDAC-mediated inhibition of p53 activity was greatly abolished (compare
lanes 3-5 in Fig. 2C, upper panel, to
lanes 3-5 in Fig. 2A, upper panel). The observed loss of HDAC-mediated inhibition was not likely due to protein instability since protein level of mutant p53 remained unchanged in the
absence or presence of HDACs (Fig. 2C, lower panel). These data are of particular interest in that the C-terminal 30 residues of
p53 contain the acetylation sites for p300/CBP (4). The acetylation of
lysines 373 and 382 of p53 has been clearly demonstrated by several
laboratories (4, 8, 9). It is reasonable to speculate that HDACs
directly deacetylate p53 at its C-terminal domain and thus alleviate
its ability to activate gene. It should be noted that deletion of
C-terminal 30 residues of p53 (wild type, 393 amino acids) did not
totally release the repression by HDACs. This can be explained in part
by the fact that additional lysine (Lys-320) is acetylated by PCAF
in vivo (8-9). Deleting the C-terminal 30 amino acids from
p53 only removed the acetylation sites for p300/CBP (Lys-373 and
Lys-382). The residual activity observed may be due to Lys-320
acetylation. Alternatively, it may be contributed by the general
phenomenon of core histone deacetylation on local promoter.
GAL4VP16-dependent Transactivation Is Not Affected by
HDACs--
To test if p53 is a specific target for HDACs, the effect
of HDACs on GAL4VP16-mediated gene activation was assayed. The
expression plasmid pSGVP that encodes GAL4VP16 was transfected into
cells in the absence or presence of HDACs. A CAT reporter construct containing five GAL4-binding sites upstream of the E1B TATA was used.
As shown in Fig. 2D, overexpression of HDACs exhibited
little effect on GAL4VP16-dependent transactivation
(compare lanes 3-5 to lane 2, upper
panel), demonstrating the specificity of HDACs on the repression
of p53 activity. This finding clearly indicates that HDACs only
regulate a subset of transcription factors. It is possible that
GAL4VP16 does not physically interact with HDACs and thus fails to
recruit HDACs to the specific promoter. In contrast, p53, presumably
its C-terminal domain, is likely to be one of the direct sites for the
binding of HDACs.
Direct Interactions of p53 and HDACs--
The results described
above are consistent with the notion that HDACs might directly
deacetylate p53, reduce its DNA-binding ability, and therefore render
it less active in stimulating gene transcription. If deacetylation of
p53 is relevant for its transcriptional activity in vivo,
then associations between p53 and HDACs should be determined. To
examine whether HDACs directly interact with p53, the ability of
GST-HDAC fusion proteins to interact with in vitro
translated 35S-labeled p53 was investigated by a protein
pull-down assay (Fig. 3A).
Remarkably, we found that HDAC1, -2, and -3 (linked to GST) retained
35S-labeled p53 to similar intensity (lanes
3-5). In contrast, GST alone showed little affinity toward p53
(lane 2). These data indicate that p53 might directly
interact with HDAC1, -2, and -3 in vitro. Our results
conflict with the conclusions made by Murphy et al. (25). In
their study, p53 inhibited downstream genes by indirect association
with HDACs, basically mediated by the corepressor mSin3A. No direct
interactions between p53 and HDACs were observed in their in
vitro GST pull-down assays. This discrepancy can be argued by the
fact that GST-p53 recombinantly purified from bacteria, instead of the
in vitro translated p53, was used in their pull-down experiments. It is of interest to note that we did not observe significant association between p53 and HDACs as well, when GST-p53 expressed in bacteria was used (data not shown). Only p53 translated in vitro in the rabbit reticular lysates was evident to
interact with HDACs (Fig. 3A). Given that HDAC1, -2, and -3 directly interact with the DNA-binding protein YY1 (22, 28), we believe
p53 might as well directly associate with HDACs independently of
mSin3A. This hypothesis is further strengthened by the fact that,
indeed, mSin3A does not exist in the rabbit reticular lysates, as
determined by a Western blotting using an antibody directed against
mSin3A (data not shown). In addition, unless the protein level of the endogenous mSin3A in H1299 cells and Saos-2 cells is high, the observed
loss of p53 activity in the presence of overexpressed wild type HDACs
shown in Fig. 1 is unlikely due to indirect mediation by mSin3A. It is
likely that certain modification(s) absent in the prokaryotic system
renders p53 a better substrate for HDACs. Nevertheless, we cannot
exclude the possibility that some proteins, which are present in the
rabbit reticular lysates, mediate the interaction.
To confirm further that the FLAG-tagged HDACs are associated with p53
in cells, p53V143A was therefore transfected into H1299 cells along
with either wild type HDAC1 (FLAG-tagged) (Fig. 3B, lane 3) or with the deacetylase mutant (H199F) (lane
4). The anti-p53 antibody (FL-393, goat polyclonal, Santa Cruz
Biotechnology) was then used to precipitate p53 and p53-associated
proteins, which were subsequently detected by Western blot analysis. As
shown in Fig. 3B, we found that both wild type and mutant
FLAG-HDAC1 could be co-precipitated with p53 (compare lanes 3, 4 to lane 2), as revealed by the Western blotting using
anti-FLAG antibodies. These data are consistent with previous
observations made by Murphy et al. (25) in which endogenous
p53 associates with HDAC1. Furthermore, our results strongly suggest
that p53 may form a complex with HDACs via direct binding (see Fig.
3A). In addition, the association of p53 and deacetylase
mutant HDAC1 (H199F) further supports the idea that deacetylase
activity is indeed required for HDACs to fully repress p53 function
(Fig. 2B).
p53 Deacetylation by HDAC1 in Vitro and in Vivo--
Because
direct associations of p53 and HDACs were demonstrated (Fig. 3), and
because the down-regulation of p53 function by HDACs was found to
target the region in p53 containing acetylation lysines for p300/CBP
(see Fig. 2C), we asked further if p53 served as a direct
substrate for HDACs. To test this hypothesis, a peptide corresponding
to the C-terminal 26 residues of p53 was synthesized and chemically
acetylated in vitro (see "Materials and Methods"). Wild
type or deacetylase mutant HDAC1 (FLAG-tagged) was expressed in the
cells, and the HDAC1 immunocomplex was precipitated by FLAG antibodies
to test its ability to deacetylate the p53 peptides that were
[3H]acetate-labeled in vitro. As shown in Fig.
4A, in the presence of the
immunoprecipitated wild type HDAC1 (wt HDAC1), we found that
the chemically acetylated p53 peptides were significantly deacetylated,
as measured by the released dpm of [3H]acetate. By
contrast, the immunoprecipitated deacetylase mutant HDAC1(H199F) only
deacetylated the p53 peptides to a background level (mt
HDAC1). As a control, a similar experiment using acetylated histone H4 peptides, a putative substrate for HDACs, as substrates was
done in parallel. Under the same conditions, we found that deacetylation of the p53 peptide by HDAC1 was comparative to H4 deacetylation, suggesting p53 could be as an equally good substrate as
histone H4 for HDACs.
We next sought to establish whether p53 could be deacetylated by HDACs
in vivo. To this end, p53V143A was introduced into H1299
cells in the absence or presence of FLAG-HDAC1. Immunoprecipitation of
the acetylated fractions of p53 was carried out by an antibody that
specifically recognizes p53 acetylated at lysines 373 and 382, followed
by a Western blot using p53-specific antiserum Ab-6 (Calbiochem). As
depicted in Fig. 4B, the acetylation level of p53 was
significantly reduced when HDAC1 was introduced into cells (upper
panel, compare lane 4 to lane 2). Again, the
p53 protein level remains unchanged in the presence of ectopically
expressed HDAC1 (lower panel, compare lane 4 to
lane 2). Similar results were obtained when
immunoprecipitation with p53 antibody (FL-393) was followed by Western
blottings for acetylated p53 (Fig. 4C, compare lane
2 to lane 1). Furthermore, the observed loss of p53 acetylation in the presence of HDAC1 was partly restored when deacetylase mutant HDAC1(H199) was introduced instead (Fig.
4C, compare lane 3 to lane 2). These
results strongly suggest that p53 is a physiological substrate for
histone deacetylases.
HDACs Reduce the Ability of p53 to Activate BAX
Promoter--
Finally, we addressed whether HDACs affect a natural
p53-responsive system, the BAX promoter (39). Cells were transfected with a luciferase reporter gene driven by the BAX promoter and the
expression plasmid of p53V143A, in the absence or presence of HDACs. As
shown in Fig. 5, in the absence of p53,
HDACs exhibited little effect on the BAX promoter ( Conclusions--
Our results indicate that HDAC1, -2, and -3 were
able to down-regulate p53-dependent transactivation. These
reductions were specific, because they were HDAC
dosage-dependent, required the deacetylase activity of
HDACs, and were not observed with GAL4VP16-dependent transactivation. Interestingly, these HDAC-mediated repressions of p53
activity were largely attributed to the C-terminal 30 amino acids of
p53, which encompass the acetylation sites for p300/CBP. Unlike histone
acetyltransferases that often have particular substrate specificity,
histone deacetylases exhibit little substrate specificity (12, 29, 37).
This can explain why similar effects were observed among HDAC1, -2, and
-3 in the down-regulation of p53 activity. However, it should be noted
that HDAC1, -2, and -3 all belong to yeast RPD3-like enzymes (19).
Whether yeast HDA1-like enzymes also cause similar effects awaits
further investigation. As mentioned previously, p300/CBP augments p53
activity not only through histone modification but also by directly
acetylating p53 at its C-terminal lysines (4, 47). Since histone
acetylation is a reversible reaction that involves the
acetyltransferases and deacetylases (7), it is reasonable to speculate
that HDACs could also deacetylate non-histone transcription factors,
such as p53, which are substrates for histone acetyltransferases. This hypothesis is strengthened by our finding that HDACs directly bind p53
and deacetylate p53 both in vitro and in vivo.
Taken together, we found that HDAC1, -2, and -3 participate in
p53-mediated gene regulation. HDACs not only enhance the
transrepression activity of p53 (25) but also inhibit its
transactivation activity, as reported here. Our results indicate that
the inhibitory effect of HDACs on p53 transactivation is not solely due
to histone deacetylation of the promoter region. HDAC1, -2, and -3 directly interact with p53, likely resulting in its deacetylation,
thereby reducing its transcription activity.
We thank Dr. Jerry L. Workman for
comments on the manuscript. We also thank Dr. S.-L. Tsai for the
construction of pGEM3-p53.
*
This work was supported by grants from the National Health
Research Institutes (to L. J. J.), the Academia Sinica, and the National Science Council of Taiwan (to Y. S. L. and C. W. W.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, April 20, 2000 DOI 10.1074/jbc.M000202200
The abbreviations used are:
CBP, CREB-binding
protein;
HDAC, histone deacetylase;
GST, glutathione
S-transferase;
Ab, antibody;
CAT, chloramphenicol
acetyltransferase;
PRE, p53-responsive elements;
BDP, benzotriazol-l-yloxytris(dimethylamino)phosphonium
hexafluorophosphate.
Histone Deacetylases Specifically Down-regulate
p53-dependent Gene Activation*
,,§
National Health Research Institutes, 128 Yen-Chiu-Yuan Road, Sec 2, Taipei 115, Taiwan, the
§ Institute of Biomedical Sciences, Academia Sinica,
Taipei 11529, Taiwan, and the ¶ Molecular Oncology Program, H. Lee Moffitt Cancer Center and Research Institute, University of South
Florida, Tampa, Florida 33612
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
and TFIIF (10), GATA-1 (11), EKLF (erythroid
Krüppel-like factor) (12),
the Xenopus NF-Y (13), TCF (T cell
factor) (14), HMGI(Y) (15), HIV Tat protein (16), c-Myb
(17), and the most recently identified E2F1 (18). Most of these
modifications are functionally relevant in vitro and
in vivo. Since histone acetylation is a reversible reaction
controlled by the steady level of histone acetyltransferases and
histone deacetylases (7), we wonder if factor acetylation (FAT) (4) is
regulated by histone deacetylases as well (factor deacetylation, FDAC).
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
80 °C. To evaluate the
successful labeling, 1 µl of the purified peptide was taken into 100 µl of water and extracted with 400 µl of ethyl acetate for
scintillation counting. The counts were adjusted to 20,000 cpm for each
peptide deacetylase assay.
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
View larger version (26K):
[in a new window]
Fig. 1.
HDAC dosage-dependent inhibition
of p53 activity. 2.5 µg of p53 reporter construct p3PREcCAT and
0.5 µg of p53V143A expression plasmid were transfected into the human
lung carcinoma cells H1299, in the absence (lanes 2, 10 and
18) or presence of 0.5 (lanes 3, 11, and
19), 1.0 (lanes 4, 12, and 20), 2.0 (lanes 5, 13, and 21), 2.5 (lanes 6, 14, and 22), 5.0 (lanes 7, 15, and
23), and 10.0 µg (lanes 8, 16, and
24) of plasmids encoding HDAC1 (upper panel),
HDAC2 (middle panel), or HDAC3 (lower panel). A
diagram of reporter construct is shown above the
autoradiograms.
View larger version (31K):
[in a new window]
Fig. 2.
Specific inhibition of p53 activity by
HDACs. A, HDAC1, -2, and -3 down-regulate p53 function
in transient transfection assays. Upper panel, H1299 cells
were transfected with 2.5 µg of p53 reporter construct p3PREcCAT, 0.5 µg of p53V143A expression plasmid, and 2.5 µg of plasmids
expressing FLAG-HDACs, as indicated. The relative CAT activity
(RCA) is indicated above each track of the
autoradiogram. RCA is the mean fold inhibition of transcription
compared with the transactivation activity of p53 in the absence of
HDACs. Experiments were repeated three times. The standard errors were
0, ±0.09, ±0.07, and ±0.13 for lanes 2-5, respectively.
Lower panel, protein levels of p53V143A. Transient
transfections were performed as in the upper panel. Proteins
of H1299 cells transfected with the vector alone (lane 1),
with p53V143A (lane 2), or with p53V143A and HDACs
(lanes 3-5) were fractionated on a 12% SDS-polyacrylamide
gel, followed by immunoblotting with antibodies against p53. The
positions of molecular mass markers in kilodaltons are shown on the
left. B, the deacetylase activity of HDACs is required for
the repression of p53 function. C, down-regulation of p53
function by HDACs is largely attributed to the C-terminal 30 amino
acids of p53. D, GAL4VP16-dependent
transactivation is not inhibited by HDACs. The CAT reporter construct
pG5E1BCAT containing five GAL4-binding sites upstream of the E1B TATA
box was illustrated above the autoradiogram.
B-D, transfections and Western blots were performed as
described in A, except that effectors and antibodies used
were as indicated in each figure. The standard errors of the RCAs were
0, ±0.05, ±0.18, and ±0.09 for lanes 2-5 in
B; 0, ±0.11, ±0.07, and ±0.09 for lanes 2-5
in C; and 0, ±0.1, ±0.26, and ±0.21 for lanes
2-5 in D, respectively.
View larger version (33K):
[in a new window]
Fig. 3.
Interactions between p53 and HDACs in
vitro and in vivo. A,
GST-HDAC fusion proteins retain 35S-labeled p53 protein in
pull-down assays. Lane 1, input p53 protein; lanes
2-5, retention of p53 protein by GST, GST-HDAC1, GST-HDAC2, and
GST-HDAC3, respectively. The position of p53 protein is indicated by an
arrow. The positions of molecular mass markers in
kilodaltons are indicated on the left. B,
co-immunoprecipitation of p53 and HDAC1 in vivo. H1299 cells
were transfected with 20 µg each of the corresponding plasmids, as
indicated. Immunoprecipitation of the cell extract with anti-p53
(FL-393, Santa Cruz Biotechnology) was performed. The existence of
HDAC1 and p53 in the immunocomplex was revealed by Western analysis
with FLAG antibodies (Sigma) and anti-p53 (Ab-6, Calbiochem),
respectively.
View larger version (16K):
[in a new window]
Fig. 4.
Deacetylation of p53 by HDAC1 in
vitro and in vivo. A,
deacetylation of p53 peptide by immunoprecipitated HDAC1. H1299 cells
were transfected with salmon sperm DNA (control), the
plasmid encoding FLAG epitope-tagged HDAC1 (wt HDAC1), or
mutant HDAC1 defective in deacetylase activity (mt HDAC1).
Immunoprecipitates using an anti-FLAG antibody (Sigma) were incubated
with chemically acetylated peptides corresponding to the N-terminal
region of histone H4 (H4) or the C-terminal 26 residues of
p53 (p53). The HD activity was determined by the dpm of the
released [3H]acetate. The amino acid sequence of the p53
peptide is shown. Lysines 373 and 382 are indicated by
arrows. The experiments were repeated three times, and the
data shown represent the average ± S.E. B and
C, 20 µg each of the expression plasmids were transfected
into H1299 cells, as indicated. B, immunoprecipitation
(IP) of the cell extract was performed with specific
antibodies to acetylated p53 (anti-Ace p53 (Lys-373 and Lys-382),
Upstate Biotechnology Inc.), followed by Western analysis with anti-p53
(Ab-6, Calbiochem). C, anti-p53 (FL-393, goat polyclonal,
Santa Cruz Biotechnology) was used to precipitate p53. The acetylation
level of immunoprecipitated p53 was detected by anti-Ace p53 (Lys-373
and Lys-382).
p53).
Expression of p53 alone activated the BAX promoter approximately
3-4-fold, as measured by the luciferase activity (+p53, open
bar). However, in the presence of wild type, but not deacetylase
mutant, HDAC1, -2, or -3, the p53-dependent transactivation
of BAX promoter was reduced approximately 50% (+p53) (Fig.
5 and data not shown). Thus, the ability of HDACs to down-regulate p53
function was not only evident on an artificial construct containing
p53-binding sites (p3PREcCAT, the data presented above) but was also
observed with the BAX promoter, a natural system responsive to p53.
These data further support the idea that HDACs might be a
physiologically important regulator of p53.
View larger version (26K):
[in a new window]
Fig. 5.
HDAC inhibition of p53 activity on the BAX
promoter. H1299 cells were transfected with vector alone
( p53) or plasmid encoding p53 (+p53), in the
presence of salmon sperm DNA (HDAC) or plasmids encoding
HDAC1 (+HDAC1), HDAC2 (+HDAC2), HDAC3
(+HDAC3). After harvesting the cells, lysates were assayed
for luciferase activity. All relative luciferase activity was
normalized with control Renilla luciferase expression. The
data shown represent the average ± S.E. of three independent
experiments.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed. Tel.:
886-2-26534401 (ext. 8000); Fax: 886-2-26513742; E-mail:
kenwu@nhri.org.tw.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
1.
Oren, M.
(1999)
J. Biol. Chem.
274,
36031-36034
2.
Sionov, R. V.,
and Haupt, Y.
(1999)
Oncogene
18,
6145-6157
3.
Ko, L. J.,
and Prives, C.
(1996)
Genes Dev.
10,
1054-1072
4.
Gu, W.,
and Roeder, R. G.
(1997)
Cell
90,
595-606
5.
Bannister, A. J.,
and Kouzarides, T.
(1996)
Nature
384,
641-643
6.
Ogryzko, V. V.,
Schiltz, R. L.,
Russanova, V.,
Howard, B. H.,
and Nakatani, Y.
(1996)
Cell
87,
953-959
7.
Workman, J. L.,
and Kingston, R. E.
(1998)
Annu. Rev. Biochem.
67,
545-579
8.
Sakaguchi, K.,
Herrera, J. E.,
Saito, S.,
Miki, T.,
Bustin, M.,
Vassilev, A.,
Anderson, C. W.,
and Appella, E.
(1998)
Genes Dev.
12,
2831-2841
9.
Liu, L.,
Scolnick, D. M.,
Trievel, R. C.,
Zhang, H. B.,
Marmorstein, R.,
Halazonetis, T. D.,
and Berger, S. L.
(1999)
Mol. Cell. Biol.
19,
1202-1209
10.
Imhof, A.,
Yang, X. J.,
Ogryzko, V. V.,
Nakatani, Y.,
Wolffe, A. P.,
and Ge, H.
(1997)
Curr. Biol.
7,
689-692
11.
Boyes, J.,
Byfield, P.,
Nakatani, Y.,
and Ogryzko, V.
(1998)
Nature
396,
594-598
12.
Zhang, W.,
and Bieker, J. J.
(1998)
Proc. Natl. Acad. Sci. U. S. A.
95,
9855-9860
13.
Li, Q.,
Herrler, M.,
Landsberger, N.,
Kaludov, N.,
Ogryzko, V. V.,
Nakatani, Y.,
and Wolffe, A. P.
(1998)
EMBO J.
17,
6300-6315
14.
Waltzer, L.,
and Bienz, M.
(1998)
Nature
395,
521-525
15.
Munshi, N.,
Merika, M.,
Yie, J.,
Senger, K.,
Chen, G.,
and Thanos, D.
(1998)
Mol. Cell
2,
457-467
16.
Kiernan, R. E.,
Vanhulle, C.,
Schiltz, L.,
Adam, E.,
Xiao, H.,
Maudoux, F.,
Calomme, C.,
Burny, A.,
Nakatani, Y.,
Jeang, K. T.,
Benkirane, M.,
and Van Lint, C.
(1999)
EMBO J.
18,
6106-6118
17.
Tomita, A.,
Towatari, M.,
Tsuzuki, S.,
Hayakawa, F.,
Kosugi, H.,
Tamai, K.,
Miyazaki, T.,
Kinoshita, T.,
and Saito, H.
(2000)
Oncogene
19,
444-451
18.
Martinez-Balbas, M. A.,
Bauer, U. M.,
Nielsen, S. J.,
Brehm, A.,
and Kouzarides, T.
(2000)
EMBO J.
19,
662-671
19.
Ayer, D. E.
(1999)
Trends Cell Biol.
9,
193-198
20.
Ng, H. H.,
and Bird, A.
(2000)
Trends Biochem. Sci.
25,
121-126
21.
Taunton, J.,
Hassig, C. A.,
and Schreiber, S. L.
(1996)
Science
272,
408-411
22.
Yang, W. M.,
Inouye, C.,
Zeng, Y.,
Bearss, D.,
and Seto, E.
(1996)
Proc. Natl. Acad. Sci. U. S. A.
93,
12845-12850
23.
Pazin, M. J.,
and Kadonaga, J. T.
(1997)
Cell
89,
325-328
24.
Ng, H. H.,
and Bird, A.
(1999)
Curr. Opin. Genet. & Dev.
9,
158-163
25.
Murphy, M.,
Ahn, J.,
Walker, K. K.,
Hoffman, W. H.,
Evans, R. M.,
Levine, A. J.,
and George, D. L.
(1999)
Genes Dev.
13,
2490-2501
26.
Zhang, Y.,
Ng, H. H.,
Erdjument, B. H.,
Tempst, P.,
Bird, A.,
and Reinberg, D.
(1999)
Genes Dev.
13,
1924-1935
27.
Wade, P. A.,
Gegonne, A.,
Jones, P. L.,
Ballestar, E.,
Aubry, F.,
and Wolffe, A. P.
(1999)
Nat. Genet.
23,
62-66
28.
Yang, W. M.,
Yao, Y. L.,
Sun, J. M.,
Davie, J. R.,
and Seto, E.
(1997)
J. Biol. Chem.
272,
28001-28007
29.
Emiliani, S.,
Fischle, W.,
Van-Lint, C.,
Al-Abed, Y.,
and Verdin, E.
(1998)
Proc. Natl. Acad. Sci. U. S. A.
95,
2795-2800
30.
Grozinger, C. M.,
Hassig, C. A.,
and Schreiber, S. L.
(1999)
Proc. Natl. Acad. Sci. U. S. A.
96,
4868-4873
31.
Verdel, A.,
and Khochbin, S.
(1999)
J. Biol. Chem.
274,
2440-2445
32.
Fischle, W.,
Emiliani, S.,
Hendzel, M. J.,
Nagase, T.,
Nomura, N.,
Voelter, W.,
and Verdin, E.
(1999)
J. Biol. Chem.
274,
11713-11720
33.
Miska, E. A.,
Karlsson, C.,
Langley, E.,
Nielsen, S. J.,
Pines, J.,
and Kouzarides, T.
(1999)
EMBO J.
18,
5099-5107
34.
Yoshida, M.,
Kijima, M.,
Akita, M.,
and Beppu, T.
(1990)
J. Biol. Chem.
265,
17174-17179
35.
Tsai, H. L.,
Kou, G. H.,
Chen, S. C.,
Wu, C. W.,
and Lin, Y. S.
(1996)
J. Biol. Chem.
271,
3534-3540
36.
Laherty, C. D.,
Yang, W. M.,
Sun, J. M.,
Davie, J. R.,
Seto, E.,
and Eisenman, R. N.
(1997)
Cell
89,
349-356
37.
Hassig, C. A.,
Tong, J. K.,
Fleischer, T. C.,
Owa, T.,
Grable, P. G.,
Ayer, D. E.,
and Schreiber, S. L.
(1998)
Proc. Natl. Acad. Sci. U. S. A.
95,
3519-3524
38.
Lillie, J. W.,
and Green, M. R.
(1989)
Nature
338,
39-44
39.
Miyashita, T.,
and Reed, J. C.
(1995)
Cell
80,
293-299
40.
Takebe, Y.,
Seiki, M.,
Fujisawa, J.,
Hoy, P.,
Yokota, K.,
Arai, K.,
Yoshida, M.,
and Arai, N.
(1988)
Mol. Cell. Biol.
8,
466-472
41.
Hsu, Y. S.,
Tang, F. M.,
Liu, W. L.,
Chuang, J. Y.,
Lai, M. Y.,
and Lin, Y. S.
(1995)
J. Biol. Chem.
270,
6966-6974
42.
Smith, D. B.,
and Johnson, K. S.
(1988)
Gene (Amst.)
67,
31-40
43.
Lin, Y. S.,
and Green, M. R.
(1991)
Cell
64,
971-981
44.
Lin, Y. S.,
Ha, I.,
Maldonado, E.,
Reinberg, D.,
and Green, M. R.
(1991)
Nature
353,
569-571
45.
Dignam, J. D.,
Lebovitz, R. M.,
and Roeder, R. G.
(1983)
Nucleic Acids Res.
11,
1475-1489
46.
Ginsberg, D.,
Mechta, F.,
Yaniv, M.,
and Oren, M.
(1991)
Proc. Natl. Acad. Sci. U. S. A.
88,
9979-9983
47.
Gu, W.,
Shi, X. L.,
and Roeder, R. G.
(1997)
Nature
387,
819-823
48.
Kadosh, D.,
and Struhl, K.
(1998)
Genes Dev.
12,
797-805
Copyright © 2000 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
 |
|
  J. Pallos, L. Bodai, T. Lukacsovich, J. M. Purcell, J. S. Steffan, L. M. Thompson, and J. L. Marsh Inhibition of specific HDACs and sirtuins suppresses pathogenesis in a Drosophila model of Huntington's disease Hum. Mol. Genet., December 1, 2008; 17(23): 3767 - 3775. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 W.-W. Tsai, T. T. Nguyen, Y. Shi, and M. C. Barton p53-Targeted LSD1 Functions in Repression of Chromatin Structure and Transcription In Vivo Mol. Cell. Biol., September 1, 2008; 28(17): 5139 - 5146. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A. Miyanaga, A. Gemma, R. Noro, K. Kataoka, K. Matsuda, M. Nara, T. Okano, M. Seike, A. Yoshimura, A. Kawakami, et al. Antitumor activity of histone deacetylase inhibitors in non-small cell lung cancer cells: development of a molecular predictive model Mol. Cancer Ther., July 1, 2008; 7(7): 1923 - 1930. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 J. Fan, H. Ren, N. Jia, E. Fei, T. Zhou, P. Jiang, M. Wu, and G. Wang DJ-1 Decreases Bax Expression through Repressing p53 Transcriptional Activity J. Biol. Chem., February 15, 2008; 283(7): 4022 - 4030. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. Enya, H. Hayashi, T. Takii, N. Ohoka, S. Kanata, T. Okamoto, and K. Onozaki The interaction with Sp1 and reduction in the activity of histone deacetylase 1 are critical for the constitutive gene expression of IL-1{alpha} in human melanoma cells J. Leukoc. Biol., January 1, 2008; 83(1): 190 - 199. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 L. J. Costa and H. A. Drabkin Renal Cell Carcinoma: New Developments in Molecular Biology and Potential for Targeted Therapies Oncologist, December 1, 2007; 12(12): 1404 - 1415. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. J.-L. Riley and L. J. Maher III p53 RNA interactions: New clues in an old mystery RNA, November 1, 2007; 13(11): 1825 - 1833. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 S. M. Lee, J. H. Bae, M. J. Kim, H. S. Lee, M. K. Lee, B. S. Chung, D. W. Kim, C. D. Kang, and S. H. Kim Bcr-Abl-Independent Imatinib-Resistant K562 Cells Show Aberrant Protein Acetylation and Increased Sensitivity to Histone Deacetylase Inhibitors J. Pharmacol. Exp. Ther., September 1, 2007; 322(3): 1084 - 1092. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H. J. Kim, M. Rowe, M. Ren, J.-S. Hong, P.-S. Chen, and D.-M. Chuang Histone Deacetylase Inhibitors Exhibit Anti-Inflammatory and Neuroprotective Effects in a Rat Permanent Ischemic Model of Stroke: Multiple Mechanisms of Action J. Pharmacol. Exp. Ther., June 1, 2007; 321(3): 892 - 901. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
B. G. Kang, J. H. Shin, J. K. Yi, H. C. Kang, J. J. Lee, H. S. Heo, J. H. Chae, I. Shin, and C. G. Kim Corepressor MMTR/DMAP1 Is Involved in both Histone Deacetylase 1- and TFIIH-Mediated Transcriptional Repression Mol. Cell. Biol., May 15, 2007; 27(10): 3578 - 3588. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H. Higashitsuji, H. Higashitsuji, T. Masuda, Y. Liu, K. Itoh, and J. Fujita Enhanced Deacetylation of p53 by the Anti-apoptotic Protein HSCO in Association with Histone Deacetylase 1 J. Biol. Chem., May 4, 2007; 282(18): 13716 - 13725. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. L. Harms and X. Chen Histone Deacetylase 2 Modulates p53 Transcriptional Activities through Regulation of p53-DNA Binding Activity Cancer Res., April 1, 2007; 67(7): 3145 - 3152. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 Y. Itoh, H. Hayashi, K. Miyazawa, S. Kojima, T. Akahoshi, and K. Onozaki 17beta-Estradiol Induces IL-1{alpha} Gene Expression in Rheumatoid Fibroblast-Like Synovial Cells through Estrogen Receptor {alpha} (ER{alpha}) and Augmentation of Transcriptional Activity of Sp1 by Dissociating Histone Deacetylase 2 from ER{alpha} J. Immunol., March 1, 2007; 178(5): 3059 - 3066. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 G. Faraco, T. Pancani, L. Formentini, P. Mascagni, G. Fossati, F. Leoni, F. Moroni, and A. Chiarugi Pharmacological Inhibition of Histone Deacetylases by Suberoylanilide Hydroxamic Acid Spec |
