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Molecular and Cellular Biology, October 2001, p. 6470-6483, Vol. 21, No. 19
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.19.6470-6483.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
ETO, a Target of t(8;21) in Acute Leukemia, Makes
Distinct Contacts with Multiple Histone Deacetylases and Binds
mSin3A through Its Oligomerization Domain
Joseph M.
Amann,1,2
John
Nip,1,2
David K.
Strom,1,2,
Bart
Lutterbach,1,2
Hironori
Harada,3
Noel
Lenny,3,4
James R.
Downing,3
Shari
Meyers,5 and
Scott W.
Hiebert1,2,*
Department of
Biochemistry1 and Vanderbilt-Ingram
Cancer Center,2 Vanderbilt University School of
Medicine, Nashville, Tennessee 37232; Departments of
Pathology3 and Tumor Cell
Biology,4 St. Jude Children's Research
Hospital, Memphis, Tennessee 38105; and Department of
Biochemistry and Molecular Biology and the Feist-Weiller Cancer Center,
Louisiana State University Health Services Center, Shreveport,
Louisiana 71130-39325
Received 26 February 2001/Returned for modification 5 April
2001/Accepted 26 June 2001
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ABSTRACT |
t(8;21) and t(16;21) create two fusion proteins, AML-1-ETO and
AML-1-MTG16, respectively, which fuse the AML-1 DNA binding domain to
putative transcriptional corepressors, ETO and MTG16. Here, we show
that distinct domains of ETO contact the mSin3A and N-CoR corepressors
and define two binding sites within ETO for each of these corepressors.
In addition, of eight histone deacetylases (HDACs) tested, only the
class I HDACs HDAC-1, HDAC-2, and HDAC-3 bind ETO. However, these HDACs
bind ETO through different domains. We also show that the murine
homologue of MTG16, ETO-2, is also a transcriptional corepressor that
works through a similar but distinct mechanism. Like ETO, ETO-2
interacts with N-CoR, but ETO-2 fails to bind mSin3A. Furthermore,
ETO-2 binds HDAC-1, HDAC-2, and HDAC-3 but also interacts with HDAC-6
and HDAC-8. In addition, we show that expression of AML-1-ETO causes
disruption of the cell cycle in the G1 phase. Disruption of
the cell cycle required the ability of AML-1-ETO to repress
transcription because a mutant of AML-1-ETO, 
469, which removes the
majority of the corepressor binding sites, had no phenotype. Moreover,
treatment of AML-1-ETO-expressing cells with trichostatin A, an HDAC
inhibitor, restored cell cycle control. Thus, AML-1-ETO makes distinct
contacts with multiple HDACs and an HDAC inhibitor biologically
inactivates this fusion protein.
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INTRODUCTION |
The acute myeloid leukemia 1 (AML-1)
gene is one of the most frequently mutated genes in human leukemia and
is disrupted by multiple chromosomal translocations in AML, including
t(8;21) and t(16;21) (9, 35, 38). t(8;21) is the most
frequent of these translocations, and it contains the AML-1 DNA binding domain fused to a transcriptional corepressor, ETO (also known as MTG8)
(4, 5, 34). t(16;21), although rarer, fuses the AML-1 DNA
binding domain to an ETO-related protein, MTG16 (9). AML-1
is also indirectly affected by
inv(16), which fuses CBF
, an allosteric
regulator of AML-1, to a smooth muscle myosin heavy chain
(25).
ETO is highly related to MTG16 and a third family member, MTGR1, in
mammalian cells and Nervy in Drosophila (6).
The mammalian family members are highly conserved throughout the
proteins, with four domains conserved in Nervy. These regions are an
N-terminal domain that is also homologous to the transcriptional
coactivator TAF110 (17), a hydrophobic heptad repeat (HHR)
that mediates dimerization (3, 21), a domain of unknown
function termed the Nervy domain, and a domain containing two zinc
finger motifs that are required for contacting the central domain of
N-CoR (29). The murine homologue of MTG16 was identified
by low-stringency screening of a cDNA library by using an ETO cDNA as a
probe (3). It shares 77% overall identity with human ETO,
but within three of four conserved domains, these proteins are 92 to
96% identical, implying that they function similarly. The Nervy domain
is the least conserved domain among family members and is 86%
identical between these two proteins.
ETO is a component of a high-molecular-weight complex containing
histone deacetylases (HDACs) (29), and ETO associates with N-CoR or SMRT and mSin3A independently (10, 29). Incapable of binding DNA directly, ETO and the associated corepressors can be
recruited to chromatin through interactions with DNA binding proteins.
For example, ETO binds the promyelocytic zinc finger protein PLZF,
which is a DNA binding transcriptional repressor that is disrupted by
t(11;17) in acute promyelocytic leukemia (31). The binding
of ETO to this transcription factor potentiated the repression of a
PLZF responsive promoter (32), suggesting that ETO acts as
a corepressor.
While ETO associates with mSin3 (29), nuclear hormone
corepressors (10, 29, 41), and HDACs (29),
the nature and extent of these associations have not been fully
addressed. In addition, little is known about the mechanism of action
of ETO-2 (MTG16). Therefore, we have further characterized the
mechanisms of action of ETO and ETO-2. While it was anticipated that
ETO-2 would act as a repressor when fused to a DNA binding domain, we unexpectedly found that ETO-2 did not interact with mSin3A. Based on
this observation, we demonstrated that the ETO dimerization motif
mediated one contact with mSin3A. In addition, we found that HDAC-1,
HDAC-2, and HDAC-3 all bound ETO, but with different characteristics,
suggesting that ETO may serve as a platform for multiple HDACs and
corepressors. Moreover, constitutive repressors of AML-1-regulated
genes, such as the inv (16) fusion protein or
engineered AML-1-repression domain fusion proteins, slow cell cycle
progression (2, 26, 27). Similarly, exogenous expression of AML-1-ETO inhibited cell cycle progression in the
G1 phase of the cell cycle. However, addition of
the HDAC inhibitor trichostatin A (TSA) to the cell culture media
restored normal cell cycle progression, indicating that AML-1-ETO
physically and functionally interacts with HDACs to disrupt biological functions.
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MATERIALS AND METHODS |
Plasmids.
The GAL4-thymidine kinase (TK)-luciferase
construct used in the transcription assays was described previously
(7). Several plasmids used in our assays were kindly
provided to us by the following investigators: FLAG-tagged HDAC-1 to -6 constructs were given to us by E. Seto (12), and
Myc-HDAC-8 was provided by E. Hu (18). Hemagglutinin
(HA)-HDAC-7 and full-length N-CoR tagged with the FLAG epitope were
kindly provided by R. Evans (20). CMV5-Myc-mETO-2 was
created in two steps in order to preserve the Myc tag
present in pJM mETO-2 (3). A
HindIII-XbaI fragment was generated using an
internal HindIII site and XbaI site in the
vector 3' of the cDNA insert placed into
HindIII-XbaI-cut pCMV5 and was called pCMV5
mETO-2 C-term. A second fragment generated by the
HindIII digest using a HindIII site in
the vector 5' of the Myc tag was isolated and placed into
the HindIII site of pCMV5 mETO-2 C-term, and orientation
was determined. CMV5-HA-mETO-2 and GAL mETO-2 were made by cutting
mETO-2 out of pJ3omega mETO-2 with XbaI and placing it into
the XbaI sites of pCMV5-HA2 and pCMV5 M2 (pCMV5 M2 was
described previously [7]). The pCMV5-HA series of
vectors was made by subcloning oligonucleotides encoding a start
methionine and the HA epitope into the EcoRI site of the pCMV5 vector. GAL4-ETO was constructed by releasing ETO from pBS-ETO with XhoI and placing it into the SalI site of
pCMV5 M2. Regions of ETO were made by PCR and subcloned into the
EcoRI and SalI sites of pCMV5 M2. PCR primers
pairs used were as follows: ETO amino acids (aa) 217 to 385, 5'-CGGAATTCGCTGCTCTGGATGCCAGCAC-3' and
5'-CCGCTCGAGGTCTGCTTCTTGACACCGCCT-3'; ETO aa 379 to 499, 5'-CCGCAATTGGCGGTGTCAAGAAGCAGAC-3' and
5'-CGCTCGAGCTCCGCCGCCTGCCGTTTGGC-3'; ETO aa 493 to 559, 5'-GGAATTCCAAACGGCAGGCGGCGGAG-3' and
5'-CGCTCGAGCTGCTGGGCCTGCAGGGTCTG-3'; ETO aa 553 to 604, 5'-CGGAATTCCCAGACCCTGCAGGCCCAGCAG-3' and
5'-CCGCTCGAGCTAGCGAGGGGTTGTCTCTAT-3'; ETO aa 217 to 301, the same 5' primer as aa 217 to 385 and
5'-CCGCTCGAGACGGTAACGCTGAGGTGGAGG-3'; ETO aa 259 to 343, 5'-CGGAATTCGCACTCAGAACATCCAAGCAAG-3' and
5'-CCGCTCGAGGTGACTAATCATTTCTTCTTGACG; ETO aa 300 to 385, 5'-CGGAATTCCTACCGTTTGGATGATATGGCC-3' and the same 3' primer
as the aa 217 to 385 fragment. To create the pCMV5 hETO-mETO-2
chimeric protein, a BamHI site conserved between the two
DNAs and one in the vector on the 3' side of the inserted cDNA were
used to release a C-terminal ETO-2 fragment. This fragment was placed
into a BamHI-cut pCMV5 hETO construct. A similar strategy was used to create pCMV5 Myc-mETO-2/hETO. pCMV5 Myc-mETO-2/hETO 394-446 was made by taking advantage of a BglII site
conserved between hETO and mETO-2 located at nucleotides 1416 and 1483, respectively. A BglII-BamHI fragment was released
from ETO and placed into a BamHI-cut pCMV5 Myc-ETO-2
maintaining the open reading frame. For the pCMV5 Myc-mETO2/hETO
constructs which delete the Nervy domain, mETO-2/hETO 447-488 and
mETO/hETO 394-488, the same strategy was used with a construct
having a deletion of this region, described previously
(28). The site-directed mutations DH358,359NS and D347E
were generated using overlap extension PCR. The primers that were used
to generate the DH-to-NS mutation were 5'-AGTGGAAACATCTTAACGATCTGTTAAACTGCAT-3' and
5'-ATGCAGTTTAACAGACTGTTAAGATGTTTCCACT-3' (the
changed codons are italicized). The D347E mutant was made using the
following oligonucleotides:
5'-CACAGACTAACAGAAAGAGAATGGGCA-3' and
5'-TGCCCATTCTCTTTCTGTTAGTCTGTG. All of the constructs
generated by PCR were sequenced through the Vanderbilt University
sequencing core facility to verify that no mutations were introduced.
Transcription assays.
NIH 3T3 cells were transfected using
the Superfect reagent (Qiagen) with 1 µg of GAL4-TK-luciferase, 100 ng of the appropriate GAL4-ETO, GAL4-mETO-2, or GAL4-ETO region
expression plasmids, and 200 ng of pCMV5-secreted alkaline phosphatase
(SEAP) plasmid as an internal control. Firefly luciferase activities
were measured using the Luciferase Assay System (Promega) and
normalized to SEAP activity. Cells were harvested approximately 48 to
52 h posttransfection.
Cell lines and cell cycle analysis.
C33A cells and Cos-7
cells were maintained in Dulbecco modified Eagle medium (DMEM;
BioWhittaker Inc.,Walkersville, Md.) containing 10% fetal bovine
serum, 50 U of penicillin/ml, 50 µg of streptomycin/ml, and 2 mM
L-glutamine (all from BioWhittaker). NIH 3T3 cells were maintained in DMEM containing 10% bovine serum. The culture of parental 32D.3 myeloid progenitor cells and establishment of stable cell lines was performed as previously described (15, 37). Murine erythroleukemia (MEL) cells were maintained as suspension cultures in DMEM supplemented with 10% fetal bovine serum
(BioWhittaker), 2 mM L-glutamine (BioWhittaker), 1%
penicillin G-streptomycin (Gibco-BRL, Life Technologies, Inc.) at
37°C in a 5% CO2 humidified incubator. MEL
cells were electroporated with the pTET.TAK.HYG vector (kindly provided
by Brian Van Ness, University of Minnesota). MEL cells expressing the
tet repressor DNA-binding domain fused to the VP16
transcriptional activation domain were electroporated with
pTET.AML1-ETO.Neo and selected for G418 resistance. Single-cell clones
expressing AML-1-ETO protein were identified by immunoblot analysis.
32D.3 cells stably transfected with AML-1B, A/E, or A/E 469 were
constructed as previously described (15, 37) by using the
sheep metallothionine promoter plasmid pMT-CB6. G418-resistant cells
were cloned in methylcellulose or by limiting dilution.
Cell cycle analysis was performed by flow cytometry as described
previously (37). Ten thousand total events were analyzed per sample. The ModFit computer program (Verity Software House, Topsham, Maine) was used to generate the histograms and determine the
percentage of cells within the G1 phase of the
cell cycle.
Coimmunoprecipitations and immunoblotting.
Cos-7 cells
(3 × 106 cells in 100-mm-diameter dishes)
were transfected using Lipofectamine (BRL) with 1.0 µg of expression plasmids and an appropriate amount of pCMV5 vector to maintain the
Lipofectamine-to-DNA ratio. For coexpression experiments, 1 to 2.5 µg
of pCMV5-GAL4-ETO and 2.5 µg of Flag-tagged N-CoR or HDACs were
cotransfected. Approximately 48 to 52 h posttransfection, cells
were harvested and extracted with phosphate-buffered saline supplemented with 1 µg of leupeptin/ml, 1 µg of pepstatin/ml, 0.2 mM phenylmethylsulfonyl fluoride, and 0.1 trypsin inhibitor unit
of aprotinin/ml and containing 0.5% Triton X-100, 0.1% sodium deoxycholate, and 0.1% sodium dodecyl sulfate (SDS) unless otherwise noted. For immunoprecipitations, cell lysates were sonicated and then
incubated with 50 µl of formalin-fixed Staphylococcus
aureus cells (Pansorbin; CalBiochem) for 30 min to remove proteins
nonspecifically binding to protein A. After centrifugation for 5 min at
4°C, the supernatants were collected, and a portion was removed for
immunoblot analysis and then incubated for 1 h with
affinity-purified primary antibody (K 20 anti-mSin3A [Santa Cruz
Biotechnology], anti-Myc(9E10) [Babco], and anti-HA [Babco]
antibodies). A 20-µl volume of a 50% slurry of protein A-Sepharose
(Pharmacia Biotech, Uppsala, Sweden) or protein G-Sepharose (Sigma) was
then added for 30 min to collect the immune complexes, and these
complexes were washed three times at 4°C with lysis buffer. For FLAG
coimmunoprecipitations, 20 µl of a 50% slurry of anti-FLAG M2 beads
(Sigma) was added to the lysates, incubated for 90 min at 4°C, and
washed three times at 4°C with lysis buffer. Protein A-Sepharose,
protein G-Sepharose, and FLAG beads were blocked in PBS containing 1%
bovine serum albumin prior to addition to the lysate.
For immunoblot analysis, the cell lysate was electrophoresed through
10% polyacrylamide gels or Criterion 4 to 20% gradient
gels
(Bio-Rad), transferred onto Immobilon-P (Millipore) or nitrocellulose
(Schleicher and Schuell), and probed with the indicated antibodies.
Immune complexes were detected using the Super Signal chemiluminescence
detection system (Pierce) and a horseradish peroxidase-labeled
goat
anti-rabbit or rabbit anti-mouse secondary antibody (Sigma).
Proteins
were detected using purified rabbit polyclonal antibodies
specific to
the N- or C-terminal domains of ETO, rabbit polyclonal
antibody to the
AML RHD, and mouse monoclonal antibodies to the
GAL4 DNA binding domain
(Santa Cruz), FLAG (Sigma), HA (Babco),
or Myc (Babco) epitopes. For
immunoblot analysis, one-tenth of
the total lysate from the
immunoprecipitations or 100 µg of protein
(quantitated with the
Bio-Rad DC protein assay) or immune complexes
were boiled in Laemmli
buffer for 3 min, fractionated by SDS-polyacrylamide
gel
electrophoresis (PAGE), and transferred to nitrocellulose.
These
membranes were blocked for 1 h with 5% milk, and incubated
with
the indicated primary antibody overnight at 4°C. Proteins
were
visualized by chemiluminesence (Super Signal;
Pierce).
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RESULTS |
ETO-2, like ETO, represses transcription.
ETO is a
transcriptional repressor when fused to the GAL4 DNA binding domain and
its activity is measured using a promoter consisting of four GAL4
binding sites upstream of a minimal TK promoter (39). To
test the ability of ETO-2 to repress transcription, chimeric proteins
were made which fused the GAL4 DNA binding domain to the N terminus of
ETO or ETO-2 (Fig. 1A). These plasmids
were cotransfected with GAL-TK-luciferase reporter plasmids, and the luciferase activity was normalized to an internal control for transfection efficiency (Fig. 1B). Both ETO and ETO-2 were potent repressors in this assay (Fig. 1B).
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FIG. 1.
ETO-2 represses transcription when tethered to a
promoter. (A) Schematic diagram of the Gal4-TK-luciferase reporter
plasmid and the GAL4-ETO and GAL4-ETO-2 fusion proteins. (B) ETO and
ETO-2 repress transcription. GAL4-ETO and GAL4-ETO-2 were transfected
with the GAL4 reporter plasmid into NIH 3T3 cells, and relative light
units were measured. The data are graphed as the relative fold
repression after correction for transfection efficiency.
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ETO-2 does not associate with mSin3A but binds N-CoR.
ETO
represses transcription by associating with several corepressor
molecules, including mSin3A, N-CoR, SMRT, HDAC-1, and HDAC-2 (10,
29, 41), though the nature of these contacts has yet to be
defined. To determine if ETO-2 represses transcription through a
similar mechanism, epitope-tagged forms of ETO and ETO-2 were
transiently expressed, cell lysates were immunoprecipitated with
anti-mSin3A antibody, and ETO and ETO-2 were detected by immunoblot
analysis. As shown previously (29), ETO copurified with
mSin3A (Fig. 2A). Unexpectedly, ETO-2
failed to associate with mSin3A, suggesting a mechanism of repression
distinct from ETO. In addition, we coexpressed ETO-2 with FLAG-tagged
N-CoR to detect a possible association. HA-ETO-2 was found in the
anti-FLAG immune complexes only when FLAG-N-CoR was coexpressed (Fig.
2B). Similar interactions were seen with the N-CoR-related SMRT
corepressor (data not shown). Therefore, ETO-2 contacts N-CoR but not
mSin3A.
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FIG. 2.
ETO and ETO-2 associate with corepressors. Cos-7 cells
were transfected with HA-ETO or Myc-ETO-2, and cell lysates were
immunoprecipitated (IP) with anti-mSin3A antibody (A) or were
transfected with FLAG-tagged N-CoR and HA-ETO-2 or HA-ETO-2 alone and
immunoprecipitated with anti-FLAG antibody (B). Proteins were detected
by immunoblot analysis using anti-mSin3A, anti-HA, and anti-Myc
antibodies. The bottom panels show the level of expression of ETO and
ETO-2. The arrow indicates the presence of a background band.
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The observation that ETO, but not ETO-2, bound mSin3A suggested that
the mSin3A interaction occurred through residues that
are not conserved
between ETO and ETO-2. The fact that deletion
of several conserved
regions of ETO, including the HHR, Nervy,
and ZnF motifs, failed to
eliminate mSin3A binding lends further
support to this conclusion
(
29). We took advantage of this distinction
to begin to
define the mSin3A binding motifs in ETO by creating
chimeric ETO/ETO-2
and ETO-2/ETO proteins (Fig.
3A). The
chimeric
proteins were constructed using unique
BamHI and
BglII restriction
sites that are conserved in both cDNAs and
maintain the open reading
frame. The chimeric proteins were expressed
in Cos-7 cells and
tested for their ability to bind mSin3A in
immunoprecipitation
assays. The ETO/ETO-2 protein copurified with
mSin3A, but the
amount of associating protein was reduced compared to
wild-type
ETO (Fig.
3B, left). By contrast, the ETO-2/ETO chimeric
protein
associated with mSin3A to a degree similar to ETO (Fig.
3B,
right
panel). Therefore, we were able to create deletions within the
ETO-2/ETO chimeric protein to further define the sequences required
for
mSin3A binding (Fig.
3A). Deletion of the conserved nervy
domain did
not affect mSin3A binding, but deletion of the region
between the HHR
and the nervy domain eliminated the mSin3A interaction
(Fig.
3B,
right).
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FIG. 3.
Mapping the C-terminal mSin3A-binding domain. (A)
Schematic diagram of ETO/ETO-2 and ETO-2/ETO chimeric proteins. (B)
Lysates were made from cells expressing the indicated chimeric proteins
and immunoprecipitated with anti-mSin3A antibody. The chimeric proteins
were detected using anti-ETO or anti-Myc antibody. Arrows indicate the
position of ETO.
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To further define the mSin3 interaction domain observed in the
ETO/ETO-2 chimeric protein, we created a series of GAL4 DNA
binding
domain-ETO fusion proteins to determine what sequences
were sufficient
for mSin3A binding (Fig.
4A).
Unfortunately, a
GAL4-ETO protein encompassing only the N-terminal 217 aa of ETO
was not expressed to levels high enough to make a clear
determination
of corepressor binding (data not shown). However,
consistent with
the analysis of ETO/ETO-2 chimeric proteins, two
domains of ETO
were sufficient for mSin3A copurification encompassing
sequences
217 to 385 and 379 to 499 (Fig.
4B, left), although in this
assay,
residues 217 to 385 appeared to bind mSin3A better than the
379-to-499
domain.
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FIG. 4.
Mapping the N-terminal mSin3A and N-CoR binding sites.
(A) Schematic diagram of the GAL4-ETO chimeric proteins. (B) Lysates
were made from cells expressing the indicated chimeric proteins and
immunoprecipitated with anti-mSin3A antibody (left). Plasmids
expressing FLAG-tagged N-CoR were cotransfected into cells with the
GAL4-ETO chimeric proteins (right) and immunoprecipitated with
anti-FLAG antibody. Chimeric proteins were detected using anti-GAL4
antibody. Arrows indicate the position of GAL4-ETO or the deletion
mutants. (C) GAL4-ETO and GAL4-ETO deletion mutants were transfected
with the GAL4 reporter plasmid into NIH 3T3 cells and relative light
units were measured. The data are graphed as relative fold repression
after correction for transfection efficiency.
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Next, we used the GAL4-ETO proteins to define the domains of ETO that
are sufficient for N-CoR binding. Although the zinc
finger motifs are
sufficient to bind the central region of N-CoR
in yeast two-hybrid
assays and mammalian two-hybrid assays (
29,
45), these
sequences are dispensable for the interaction of
AML-1-ETO with
full-length N-CoR, suggesting the presence of a
second N-CoR binding
domain (
29). Indeed, only the first domain
tested
(residues 217 to 385) copurified with N-CoR immune complexes
(Fig.
4B,
right), suggesting that this domain contains the previously
predicted
second N-CoR binding
motif.
Some of the advantages of using GAL4-ETO fusion proteins are that the
GAL4 motif provides both a nuclear localization signal
and the ability
to measure transcriptional activity of the fusion
proteins using a
GAL4-dependent reporter plasmid (Fig.
1A). Therefore,
the ability of
the ETO domains to repress transcription was defined.
Relative to
wild-type ETO, each individual domain was impaired
for repression,
consistent with the presence of multiple corepressor
binding sites in
full-length ETO (Fig.
4C). However, GAL4-ETO(217-385),
which appears to
bind mSin3A and N-CoR better than the C-terminal
fragments, was the
only domain that was capable of significant
repression. This result
agrees with the observation that deletion
of the zinc finger motif in
the context of AML-1-ETO did not dramatically
affect repression by the
fusion protein (
23).
ETO interacts with class I HDACs independent of mSin3A or
N-CoR.
Previously, we had demonstrated that ETO associated with
HDAC-1 and HDAC-2 (29). To extend this analysis, we
determined whether ETO could contact any of the known class I or class
II HDACs. Epitope-tagged forms of HDACs 1 to 8 were coexpressed with ETO, and the levels of ETO that copurified with specific HDACs were
measured by immunoblot analysis (Fig.
5A). The class I HDACs HDAC-1, HDAC-2,
and HDAC-3 all bound ETO whereas HDAC-8 only weakly associated with ETO
(Fig. 5A). However, none of the class II HDACs showed a significant
interaction with ETO. Therefore, ETO interacts with a subset of the
class I HDACs.
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FIG. 5.
ETO and ETO-2 bind multiple HDACs. (A) ETO binds HDAC-1,
HDAC-2, and HDAC-3. The numbers above the lanes indicate the
epitope-tagged form of HDAC-1 to -8 that was coexpressed with ETO.
After immunoprecipitation (IP) with anti-FLAG (FL), anti-HA (HA), or
anti-Myc (Myc) antibody, copurifying ETO was detected by immunoblot
analysis (middle). The bottom panel is an immunoblot of the cell
lysates prior to immunoprecipitation. *, nonspecific bands and
proteolytic fragments. (B) ETO-2 binds HDACs 1, 2, 3, 6, and 8. The
experiment was performed exactly as in panel A, but using
epitope-tagged mETO-2. The numbers above the lanes indicate the
epitope-tagged HDAC that was coexpressed with ETO-2 as described for
panel A. Note that anti-HDAC antibody connotes that the experiment was
performed with antibodies to the epitope tag for that HDAC.
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Because ETO-2 interacted with N-CoR, but not mSin3A, the HDACs that
ETO-2 can bind were determined by copurification (Fig.
5B). Like ETO,
mETO-2 associated with HDAC-1, HDAC-2, and HDAC-3.
However, mETO-2 also
interacted with HDAC-6, which has a duplicated
catalytic domain and the
fourth class I family member, HDAC-8.
Therefore, ETO and mETO-2 are
capable of interacting with different
subgroups of HDACs to repress
transcription.
N-CoR interacts with the class II HDACs 4, 5, and 7 (
19,
20) and with the class I HDAC HDAC-3 (
13,
24,
43),
whereas
mSin3A binds HDAC-1, HDAC-2, and HDAC-7 (
14,
20,
22,
36).
Therefore, it is possible that HDAC binding by ETO was via
N-CoR
or mSin3A. To test this possibility, we coexpressed FLAG-tagged
HDAC-1, HDAC-2, and HDAC-3 with the GAL4-ETO chimeric proteins
to
determine whether mSin3A and HDAC binding cosegregated. All
three HDACs
tested interacted with ETO residues 493 to 559 (Fig.
6), which were not sufficient for the
copurification of either
mSin3A or N-CoR (Fig.
4B). Thus, the HDACs
bind ETO independent
of mSin3 and N-CoR. In addition, HDAC-1 and HDAC-3
bound ETO residues
217 to 385, which also contact mSin3A and N-CoR.
HDAC-3 also weakly
associated with ETO residues 379 to 499 (Fig.
6). By
contrast,
HDAC-2 poorly bound ETO residues 217 to 385 but copurified
with
ETO residues 379 to 499, which also contain a second
mSin3A-binding
site (compare Fig.
6 and
4B). Therefore, even the
homologous class
I HDACs bind ETO via separable domains.
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FIG. 6.
Mapping of the HDAC-binding sites on ETO. FLAG-tagged
HDAC-1 to -3 were coexpressed with the GAL4-ETO chimeric proteins from
Fig. 4. Copurifying GAL4-ETO proteins were detected using anti-GAL4
immunoglobulin G for immunoblot analysis. Shown are the control
anti-FLAG antibody blot showing that each HDAC was expressed and
immunoprecipitated (top), copurifying ETO fragments (middle), and the
levels of expression of the GAL4-ETO chimeric proteins (bottom).
|
|
HHR-oligomerization domain of ETO is required for mSin3A, but not
N-CoR interactions.
Because mSin3A, N-CoR, HDAC-1, and HDAC-3 all
interacted with ETO residues 217 to 385, we further subdivided this
domain to define the interacting motifs (Fig.
7A). Three overlapping fragments were fused to the GAL4 DNA binding domain and tested
for binding each corepressor in coimmunoprecipitation assays (Fig. 7B).
Only ETO residues 300 to 385, containing the HHR-dimerizaton domain, were sufficient to mediate mSin3A binding. By contrast, the first ETO
fragment containing residues 217 to 301 weakly bound N-CoR (Fig. 7B).
The second fragment (residues 259 to 343) also bound N-CoR in some
assays, suggesting a very weak association (data not shown). HDAC-3
associated with fragments containing either ETO residues 259 to 343 or
300 to 385, whereas HDAC-1 interacted only with GAL4-ETO(300-385) (Fig.
7C). Therefore, HDAC-3 either binds ETO twice within this domain or
this interaction is mediated by the residues that overlap between these
fragments (aa 300 to 343) and it binds differently than HDAC-1. Thus,
N-CoR binds a domain distinct from mSin3A, and HDAC-1 and HDAC-3 have
different binding patterns that are separable from N-CoR.
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|
FIG. 7.
Fine mapping of the N-terminal repression domain of ETO.
(A) Schematic diagram of the GAL4-ETO chimeric proteins used. (B)
mSin3A and N-CoR bind to distinct ETO domains. (Left) Lysates were made
from cells expressing the indicated chimeric proteins and
immunoprecipitated (IP) with anti-mSin3A antibody. Immune complexes
were analyzed for the presence of mSin3A (top) and GAL4-ETO proteins
(anti-GAL4 immunoblot; middle). Shown also are the levels of expression
of the GAL4-ETO chimeric proteins (bottom). (Right) GAL4-ETO chimeric
proteins were coexpressed with FLAG-N-CoR, and cell lysates containing
FLAG-tagged N-CoR were immunoprecipitated with anti-FLAG antibody.
Chimeric proteins were detected using anti-GAL4 antibody (below). (C)
HDACs bind different domains in ETO. GAL4-ETO chimeric proteins were
coexpressed with FLAG-HDAC-1 or FLAG-HDAC-3, and cell lysates
containing expressed FLAG-tagged HDAC-1 or HDAC-3 were
immunoprecipitated with anti-FLAG antibody. Chimeric proteins
copurifying were detected using anti-GAL4 antibody (middle). Shown are
the levels of expression of the GAL4-ETO chimeric proteins (bottom) and
immunoprecipitated HDAC (top).
|
|
Given that ETO residues 300 to 385 are sufficient to contact mSin3A and
that ETO-2 failed to bind mSin3A, we compared the
primary sequence of
ETO and ETO-2 in this region (Fig.
8A).
Because
GAL4-ETO(259-343) overlaps with GAL4-ETO(300-385) but does not
bind mSin3A, it is likely that residues 343 to 385 (including
the
HHR-dimerization motif) are required for this interaction.
In addition,
the region with the least homology within this sequence
(residues 319 to 333; Fig.
8A), could be deleted in the context
of GAL4-ETO(217-385)
without the loss of mSin3A binding (data
not shown). Within the
sequence from aa 343 to 385, there are
only three differences between
ETO and ETO-2 that could alter
the association with mSin3A. Therefore,
we used site-specific
mutagenesis to change these residues of ETO to
match those found
in ETO-2 within the GAL4-ETO(300-385) fusion protein.
The alteration
of the two amino acids within the HHR-dimerization
domain (D358N,
H359S) significantly impaired mSin3A binding (Fig.
8B),
whereas
the conservative D347E change just upstream of the HHR had no
effect (Fig.
8B). Thus, one of the mSin3A binding domains of ETO
overlaps with the HHR-dimerization motif.
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FIG. 8.
The HHR-dimerization motif of ETO contacts mSin3A. (A)
Comparison of the sequences of ETO and ETO-2 within the
HHR-dimerization domain. Stars highlight the differences between ETO
and ETO-2. The HHR is shown in italics. Arrows indicate the amino acids
that were changed and analyzed in panel B. The underlined sequence
indicates a region of low homology. (B) The HHR is required for binding
mSin3A. Lysates were made from cells expressing the indicated GAL4-ETO
chimeric proteins and were immunoprecipitated with anti-mSin3A
antibody. Shown are immunoprecipitated mSin3A (top), associated
GAL4-ETO proteins (middle), and the expression of the GAL4-ETO fusion
protiens (bottom). The chimeric proteins were detected using anti-GAL4
antibody.
|
|
HDAC inhibitor biologically inactivates t(8;21) fusion
protein.
The strong association of ETO with HDACs implied that the
t(8;21) fusion protein uses HDACs to alter biological phenotypes. Because of the large number of contacts (some overlapping; see Fig. 11)
between ETO and corepressors, we could not readily determine whether
AML-1-ETO function cosegregated with mutants that eliminated specific
contacts. Therefore, we used the HDAC inhibitor TSA to probe the role
of HDACs in AML-1-ETO function. While AML-1-ETO impairs myeloid cell
differentiation (1, 44), HDAC inhibitors promote
hematopoietic cell differentiation irrespective of AML-1-ETO action.
Therefore, we attempted to establish an alternate assay. Previously, we
found that AML-1 (RUNX-1) overexpression in 32D.3 myeloid progenitor
cells led to an acceleration of S-phase entry and accumulation of
S-phase cells when compared to 32D.3 cells expressing control vector
alone (40). In addition, expression of the
inv(16) or an artificial AML-1-repression domain fusion protein slowed cell cycle progression in the G1
phase (2, 26). Because AML-1-ETO and
inv(16) have similar biological actions, we
tested whether AML-1-ETO could also impair cell cycle progression.
To avoid potential problems in establishing cell lines expressing high
levels of the fusion protein, we created tetracycline-inducible
AML-1-ETO-expressing MEL cells (
11). AML-1-ETO protein
was not
detected in the presence of tetracycline, but it was strongly
induced in the absence of tetracycline (Fig.
9A). In the presence
of tetracycline,
the AML-1-ETO-expressing cells grew normally;
however, when AML-1-ETO expression was induced, these cells grew
slowly. The numbers of cells in each cell cycle phase were determined
using flow cytometry to measure DNA content after staining with
propidium iodide. AML-1-ETO-expressing cells accumulated in
G
1 with a commensurate decrease in the number of
cells in S phase
(Fig.
9B).
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FIG. 9.
AML-1-ETO-expressing cells accumulate in the
G1 phase. (A) Immunoblot analysis of AML-1-ETO in the
presence and absence of tetracycline. Cells were cultured in the
presence (+) or absence ( ) of tetracycline for 48 h prior to the
preparation of whole-cell extracts for separation by SDS-PAGE. Proteins
were detected using antibodies directed to residues 50 to 177 of AML-1
(the RHD). Arrows indicate the AML-1-ETO and AML-1B bands. Note that
the endogenous AML-1B is repressed by AML-1-ETO expression. The
numbers following the AML-1-ETO designations indicate individual
clonal cell lines. (B) Cell cycle analysis of AML-1-ETO-expressing MEL
cells. Cells were cultured in the absence of tetracycline for 48 h
before DNA content analysis was determined by flow cytometry after
staining the DNA with propidium iodide. (C) Cell cycle analysis of
AML-1-ETO-expressing 32D.3 myeloid progenitor cells. These cell lines
expressing AML-1-ETO were characterized previously (45).
DNA content analysis was determined by flow cytometry after propidium
iodide staining. Flow cytometric histograms for the indicated cell
lines are shown and the number of cells in each cell cycle phase were
determined using the ModFit algorithm. (D) A transcriptionally inactive
deletion mutant of AML-1-ETO (469) does not disrupt cell cycle
function. Cell cycle analysis of 32D.3 cells expressing AML-1-ETO, the
deletion mutant 469, or pMT control vector alone were induced with
75 µM ZnSO4 for 16 h, and aliquots were processed
for flow cytometric analysis. The names of the 32D.3-derived cell lines
are labeled at the top of each panel and the percentages of cells in
each phase of the cell cycle, as determined by the ModFit analysis
program, are shown within each panel. The apoptotic cells and debris
were gated and are not shown in the histograms.
|
|
To confirm that this effect was not cell type specific, we used our
previously characterized 32D.3 cell lines expressing the
fusion protein
from the zinc-inducible metallothionine promoter
(
44). We
measured the number of cells in each cell cycle phase
by using
propidium iodide staining of DNA and flow cytometry to
measure DNA
content 48 h after zinc induction of AML-1-ETO expression
(Fig.
9C). AML-1-ETO-expressing cells, but not control cells,
accumulated
with a 2N DNA content indicative of a slowing of
G
1 phase
transit.
As a further control for this phenotype, we used a C-terminal deletion
mutant of AML-1-ETO (AML-1-ETO
469), which removes
ETO sequences C
terminal to the TAF110 domain (including both
mSin3A binding sites, one
N-CoR binding site, and the majority
of HDAC-binding sites; Fig.
2 to
6) and no longer represses transcription
(
23). This mutant
failed to alter the cell cycle profile of
32D.3 cells (Fig.
9D, right).
By contrast, cells expressing AML-1-ETO
showed a significant
G
1 arrest, with a concomitant decrease in
S phase
(Fig.
9D, middle) when compared to control 32D.3 cells
containing the
empty vector (Fig.
9D, left). The results with
the
469 mutant
suggest that transcriptional repression mediated
by the AML-1-ETO
fusion protein may be critical for induction
of this aberrant cell
cycle
phenotype.
Next, we used the AML-1-ETO-mediated inhibition of cell cycle
progression to biologically test the role of HDACs in AML-1-ETO
function. MEL cells expressing AML-1-ETO were cultured in the
absence
of tetracycline to induce protein expression in the presence
or absence
of 0.05 µM TSA. Consistent with previous experiments,
AML-1-ETO
overexpression caused cells to arrest in the G
1
phase.
TSA effectively abrogated the G
1 phase
accumulation induced by
AML-1-ETO but had no effect on control cell
lines (Fig.
10). Therefore,
AML-1-ETO
likely inhibits cell cycle progression by repressing
AML-1 target gene
expression and HDAC inhibitors specifically
inactivate AML-1-ETO.
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FIG. 10.
TSA ablates the AML-1-ETO-induced G1 phase
accumulation of cells. Cell cycle analysis of AML-1-ETO-expressing
(A/E) and control (MEL) cell lines by using propidium iodide staining
and flow cytometry were used to measure DNA content. The
indicated cell lines (lines 5, 10, and 14) were cultured in media
containing or lacking tetracycline. After washing the cells to remove
tetracycline, half of the cells were cultured in the presence of 0.05 µM TSA. Cell cycle histograms were compiled using the ModFit
algorithm.
|
|
| |
DISCUSSION |
The molecular contacts between the ETO zinc finger motif and the
nuclear hormone corepressors N-CoR and SMRT have been defined by yeast
two-hybrid assays, mammalian two-hybrid assays, and purification studies (10, 29, 41, 45). However, our approach of
defining domains of ETO that are sufficient for corepressor binding by using chimeric ETO/ETO-2 and GAL4-ETO proteins has defined multiple contacts between ETO, N-CoR, mSin3A, HDAC-1, HDAC-2, and HDAC-3 (the
known molecular contacts for ETO are summarized in Fig.
11A). By using overlapping fragments of
ETO as GAL4-ETO fusion proteins, we were able to separate closely
adjoining binding sites for corepressors. For example, HDAC-3 bound
both GAL4-ETO(259-343) and GAL4-ETO(300-385), indicating that the
binding site likely resides in the region of overlap between these
fragments (residues 300 to 343). By contrast, mSin3A bound to only
GAL4-ETO(300-385), placing this binding site C terminal to HDAC-3 (Fig.
11A). These results are consistent with the recent identification of an
mSin3A binding site that overlapped the HHR domain (16).
However, our results using point mutations indicated that the
HHR-dimerization domain of ETO contacts mSin3A (Fig. 8). Although we
were able to define a second mSin3A binding site between the HHR and
nervy domain by using the ETO/ETO-2 fusion proteins, we were not able
to use this strategy to map the second HDAC-2 binding site because
HDAC-2 also bound ETO-2 (Fig. 5B).
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FIG. 11.
Hypothetical model of ETO and ETO-2 corepression
complexes. (A) Schematic diagram of the domains of ETO that bind
corepressors. Arrows indicate where the stated proteins contact ETO
based on the analysis in this work and work previously described
(10, 29, 41). TAF110, a region of ETO with homology to
Drosophila TAF110; HHR, hydrophobic heptad repeat; ND,
nervy homology domain; Zn, the predicted dual zinc finger motif. (B)
Model of ETO-containing complexes. (C) Model of ETO-2-containing
complexes. ?, potential corepressor interactions yet to be
identified.
|
|
ETO is the prototype of a family of highly homologous evolutionarily
conserved proteins. Like ETO, ETO-2 is a potent repressor when tethered
to a promoter by fusing it to the GAL4 DNA binding domain (Fig. 1).
Therefore, it was unexpected that ETO, but not ETO-2, interacted with
mSin3A. In fact, while the human family members ETO and MTG16a are 67%
identical, the regions that specify mSin3A binding include one of the
least conserved regions of ETO and a subtle alteration in the
HHR-oligomerization motif. Because HDAC-1 and HDAC-2 heterodimerize and
copurify with mSin3, whereas HDAC-3 copurified with N-CoR (24,
43), we propose a model in which ETO can recruit at least two
different corepression complexes (Fig. 11B). This model is consistent
with the sucrose gradient sedimentation pattern of ETO because ETO
cosedimentated with both N-CoR and mSin3A but was found in fractions
that contained mSin3A and not N-CoR (29). However, as ETO
can bind HDACs independent of either mSin3A or N-CoR, it remains
possible that ETO is a component of multiple corepression complexes.
The lack of mSin3A binding by ETO-2 and its ability to associate with
five HDACs indicates that it is a component of a corepressor complex(es) that is distinct from ETO-containing complexes (Fig. 11C).
If ETO and ETO-2 have distinct mechanisms of action or distinct targets
for repression, this would explain why multiple family members are
expressed in the same cell type. Alternatively, the fact that ETO
family members can homo- and heterodimerize through the HHR domain adds
a further level of complexity to transcriptional regulation by this
family and may be a way of fine tuning transcriptional control in a
particular tissue (21, 28).
It has been postulated that oligomerization of ETO is critical for
interactions with N-CoR or SMRT and for AML-1-ETO biological actions
(33, 45). However, in light of our definition of
corepressor binding sites within and adjacent to the HHR-dimerization
domain of ETO, it is more likely that it was the deletion of these
corepressor binding sites that affected AML-1-ETO function
(46). In fact, the AML-1-ETO deletion that was used to
suggest a biological role for dimerization of AML-1-ETO (deletion of
ETO residues 340 to 440 as numbered here) impinged upon one HDAC-1
binding motif, both mSin3A binding domains, and possibly binding sites
for HDAC-2 and HDAC-3 (46) (Fig. 11A). By contrast, a more
specific deletion of the HHR-dimerization motif that affected only one
mSin3A-binding site had modest effects on GAL4-ETO (45)
and AML-1-ETO-mediated transcriptional repression (28).
This mutation reduced, but did not eliminate, binding to mSin3A, N-CoR,
or HDACs (references 28 and 29 and this
work). Thus, it is possible that dimerization contributes to
repression, but dimerization is not required for corepressor binding.
If indeed ETO family proteins heterodimerize, our results indicate that
association between ETO and ETO-2 could lead to the recruitment of a
distinct set of corepressors and HDACs given that ETO binds mSin3A, but
ETO-2 does not, and ETO-2 binds HDAC-6 and HDAC-8. This might broaden
the biological action of ETO and, by extension, AML-1-ETO.
Though counterintuitive, inhibition of cell cycle progression by
AML-1-ETO has a precedent in that the inv (16)
fusion protein, which also represses AML-1 target genes, caused a
slowing of cell cycle progression in the G1 phase
(2). In fact, t(8;21)-containing leukemia cell lines
(e.g., Kasumi-1) grow very slowly. Although it is difficult to
ascertain whether this phenotype is related to leukemogenesis, it does
afford us a highly reproducible biological assay with which to probe
the mechanism of action of AML-1-ETO. TSA induces cell
differentiation, cell death, and, in some cases, cell cycle inhibition,
perhaps due to induction of p21waf1/cip1
(30). Indeed, upon longer exposure of these MEL cells to
TSA, we observed partial differentiation and cell cycle arrest in both control and AML-1-ETO-expressing cells (data not shown). However, in
the short term, we observed that TSA biologically inactivated the
t(8;21) fusion protein.
The t(15;17) and t(11;17) fusion proteins also used HDACs to repress
transcription and preliminary work using inhibitors of these enzymes in
therapy was successful (42). In addition,
t(8;21)-containing blasts are sensitive to a combination of retinoic
acid and TSA (8). Our results begin to provide a
mechanistic basis for the sensitivity to TSA and further emphasize that
HDAC inhibitors can biologically inactivate AML-1-ETO. This work also
demonstrates the necessity of the development of HDAC inhibitors that
target specific classes of HDACs or specific HDACs. Although N-CoR and mSin3A bind class I and class II HDACs, the independent association of
HDAC-1, HDAC-2, and HDAC-3 with ETO suggests that treatment of patients
harboring t(8;21) may require only inhibition of the class I
deacetylases, thereby decreasing any potential toxicity associated with
a broad-spectrum HDAC inhibitor such as TSA. Moreover, our work
demonstrates the interactions that can take place, but the
constellation of corepressors and HDACs that are expressed in
t(8;21)-containing leukemic blasts will ultimately define the critical
therapeutic targets.
| |
ACKNOWLEDGMENTS |
We thank Yue Hou and Dana King for expert technical assistance
and the Vanderbilt Ingram Cancer Center sequencing facility for support.
This work was supported by National Institutes of Health grants
RO1-CA76186 (SM), RO1-AG13726, RO1-CA64140, and RO1-CA77274, American
Cancer Society grants JFRA-591 (S.W.H.) and PO1 CA71907 (J.R.D.), and a
Center grant from the National Cancer Institute (CA68485), the
Vanderbilt-Ingram Cancer Center, and the American Lebanese Syrian
Associated Charities of St. Jude Children's Research Hospital. J.N. is
a Leukemia Society of America Special Fellow (grant 3827-99).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry, Vanderbilt University School of Medicine, 23rd and
Pierce, MRB II 512, Nashville, TN 37232. Phone: (615) 936-3582. Fax:
(615) 936-1790. E-mail:
scott.hiebert{at}mcmail.vanderbilt.edu.
Present address: Department of Biology, University of South
Carolina, Aiken, SC 29801.
| |
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Molecular and Cellular Biology, October 2001, p. 6470-6483, Vol. 21, No. 19
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.19.6470-6483.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
