Cardiovascular Research Laboratories, Department of
Medicine, UCLA School of Medicine, Los Angeles, California
90095,1 and Departments of
Medicine,2 Molecular and Cellular
Biology,3 and Molecular Physiology and
Biophysics,4 Baylor College of Medicine,
Houston, Texas 77401
Received 8 May 2000/Returned for modification 10 July 2000/Accepted 14 September 2000
The retinoblastoma protein (Rb) regulates both the cell cycle and
tissue-specific transcription, by modulating the activity of factors
that associate with its A-B and C pockets. In skeletal muscle, Rb has
been reported to regulate irreversible cell cycle exit and
muscle-specific transcription. To identify factors interacting with Rb
in muscle cells, we utilized the yeast two-hybrid system, using the A-B
and C pockets of Rb as bait. A novel protein we have designated
E1A-like inhibitor of differentiation 1 (EID-1), was the predominant
Rb-binding clone isolated. It is preferentially expressed in adult
cardiac and skeletal muscle and encodes a 187-amino-acid protein, with
a classic Rb-binding motif (LXCXE) in its C terminus. Overexpression of
EID-1 in skeletal muscle inhibited tissue-specific transcription.
Repression of skeletal muscle-restricted genes was mediated by a block
to transactivation by MyoD independent of G1 exit and,
surprisingly, was potentiated by a mutation that prevents EID-1 binding
to Rb. Inhibition of MyoD may be explained by EID-1's ability to bind
and inhibit p300's histone acetylase activity, an essential MyoD
coactivator. Thus, EID-1 binds both Rb and p300 and is a novel
repressor of MyoD function.
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INTRODUCTION |
Terminal differentiation is a
process whereby highly specialized cells undergo irreversible growth
arrest and upregulate a panel of cell type-specific genes that are
required for normal cellular function. The retinoblastoma gene product,
Rb, has been implicated in mediating both the permanent cell cycle
arrest and upregulation of tissue-specific genes associated with
terminal differentiation in a wide variety of tissues (36, 38, 67, 74). Studies in skeletal muscle have determined that MyoD and other members of the basic helix-loop-helix family of myogenic transcription factors can induce both components of terminal
differentiation, namely, myogenic gene transcription and cell cycle
exit (44, 57). However, this ability appears to be dependent
on the presence of Rb. Rb-deficient myotubes dedifferentiate and
reenter the cell cycle in response to mitogens, despite the presence of
the other pocket protein family members, p107 and p130 (57).
Moreover, MyoD-transfected Rb
/ mouse embryonic
fibroblasts fail to express late markers of myogenic differentiation
and accumulate in the S and G2 phases of the cell cycle,
implying that full MyoD transcriptional activity requires the
coexpression of Rb (19, 44). The mechanism underlying this
selective requirement for Rb is controversial; however, Rb dependence
is also seen with C/EBP-mediated gene transcription in adipose
differentiation (9). Interestingly, it has been proposed
that Rb's ability to confer these two functions, namely, cell cycle
arrest and differentiation, are mediated by separate domains within the
B pocket, suggesting that Rb must interact with multiple cellular
partners for full activity (58). Developmental studies that
have correlated upregulation of Rb in myocardium in the neonatal period
with growth arrest in ventricular myocytes support the premise that Rb
may be the key to terminal differentiation in myocardium as well
(16, 67).
Adenovirus E1A protein has been used in both skeletal (69)
and cardiac (4, 32) myocytes to block pocket protein
function and determine their importance in irreversible cell cycle exit and the control of muscle-specific gene expression (39).
Cell cycle reactivation and a block to tissue-specific transcription were produced in both forms of striated muscle by E1A mutants that
selectively block pocket protein function without binding the
transcriptional coactivator, p300, a second pathway for
dedifferentiation that is also targeted by E1A (15, 32, 49).
The mechanism for dedifferentiation induced by E1A binding to pocket
proteins is unknown but theoretically could be secondary to disruption of pocket protein family members' interaction with muscle-specific factors. Therefore, a requirement for Rb seems to be a general property
in the terminal differentiation of multiple tissues, particularly
striated muscle. To begin to understand the mechanism of this
dependence, we sought to identify Rb-binding proteins in muscle tissue,
utilizing the yeast two-hybrid system. Here, we describe the
characterization of one clone isolated from a human cardiac tissue cDNA
library, which we have called designated E1A-like inhibitor of
differentiation 1 (EID-1). Like the adenoviral protein E1A, EID-1 binds
the A-B pocket of Rb, impairs transactivation by the muscle
determination protein, MyoD, and binds to p300, inhibiting its histone
acetyltransferase (HAT) activity.
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MATERIALS AND METHODS |
Plasmids.
The bait plasmid, pAS
Rb, was generated by
ligating an EcoRI-MunI fragment (amino acids
[aa] 379 to 835) of Rb into the EcoRI site of pAS2
(Clontech). pASRb2, pAS(H209), GST-Rb constructs, GAL4-SRF (aa 266 to
502), GAL4-MEF2C (aa 175 to 465), EMSV-MyoD, 4RTk-Luc, SkA-Luc,
CaA-Luc, and CMV-LacZ constructs have been described previously
(12, 40, 77). MCK-Luc was created by subcloning the 1,800-bp
BglII-HindIII fragment of the MCK gene into
pGL3 Basic (65). The p300 expression vectors and GST fusions have been previously reported (14, 27). CMV-EID-1 and
CMV-EID-1(C180G) were constructed by cloning an
EcoRI-AvaII fragment corresponding to the
full-length coding sequences into pCDNA3 (Invitrogen). FLAG fusion
proteins were constructed by ligating EID-1 (aa 3 to 187) or mutations
in frame into CMV-FLAG2 (IBI Kodak). The GAL4-binding domain
(GAL4-BD)-EID-1 vectors were constructed by cloning the
EcoRI-XbaI fragments from the corresponding FLAG
fusion constructs into p424, the GAL4-BD mammalian expression vector (53).
The point and deletion mutations in EID-1 were performed using
site-directed mutagenesis as described by Deng and Nickoloff (11). Briefly, the Transformer Site-Directed Elimination
Mutagenesis kit (Clontech) was used according to the
manufacturer's instructions, with a synthetic oligonucleotide
corresponding to the indicated mutation. The oligonucleotides used were
as follows: EID-1(C180G), 5'-GAAGAACTCGGCGGTGATGAGATTATTG-3'; EID-1dl53-61,
5'-GGGGCCCAACAGCTCGGCCCAGCCAATGGCG-3'; and
EID-1dl62-91, 5'-ATGGAGGAGGAGGAGGACTTCGAGAGCGAG-3'.
Mutation EID-1dl92-115, kindly provided by W. Kaelin, is
described in the accompanying manuscript (42).
Combinatorial mutations were constructed by fusing the indicated
fragments using convenient restriction sites. Rb-GAL4-BD fusion
mutants in pAS2 have been previously described (12). All
mutations were confirmed by DNA sequencing.
Interaction cloning.
Saccharomyces cerevisiae strain
Y190 was transformed to Trp prototrophy with ASRb using lithium
acetate (17). A single colony was grown in synthetic
complete-Trp medium and transformed with human heart libraries cloned
into pGAD10 or pACT2 (Clontech). The transformation mixture was then
plated on media lacking tryptophan, leucine, and histidine but
including 25 mM 3-amino-1,2,4-triazole (Sigma) and incubated for 5 to 7 days at 30°C. HIS+ colonies were then screened for
-galactosidase (-gal) activity using the filter lift assay. Total
DNA from true positive clones was isolated according to the method of
Hoffman and Winston (26) and used to transform KC8 cells
(Clontech) via electroporation with a Bio-Rad GenePulser according to
the manufacturer's specifications. Transformants were plated on
minimal media lacking leucine and containing ampicillin. Clones were
sequenced by automated fluorescent dideoxy sequencing.
Quantification of LacZ activity in yeast.
S.
cerevisiae cultures of 2 ml each were grown in the appropriate
selective media to an optical density at 600 nm of ~1.0. Yeast
lysates were prepared according to the protocol of Guarente (20). Quantification of -gal activity was achieved either
with chlorophenyl-red--D-galactopyranoside (CPRG)
(Boehringer Mannheim) and determining the amount of liberated
chlorophenyl red at an optical density of 574 nm or with the
luminescent LacZ substrate from Clontech.
Transfection assays.
The U2OS, C2C12, and CV-1 cell lines
were obtained from the American Tissue Culture Collection and
propagated in Dulbecco's modified Eagle's medium plus 10% fetal calf
serum (Hyclone Laboratories). L17 cells were a gift from J. Massague.
Human primary skeletal myocytes were purchased from Clonetics and
cultured according to the manufacturer's specifications. All
transfections were carried out using Lipofectamine (Life Technologies,
Inc.) according to the manufacturer's specifications. Forty-eight
hours after transfections, cell lysates were collected and analyzed for
luciferase activity normalized to that of an internal CMV-LacZ control
as previously described (40). For the experiments involving
p300, luciferase activity was corrected for total protein as previously
described (47). All experiments were repeated at least three
times with two independent batches of plasmids. Results (mean ± standard error) were compared by analysis of variance and Fisher's
PLSD tests, using a significance at a P value of <0.05.
Construction of adenoviruses.
Recombinant adenoviruses were
constructed and propagated, and the titers of the viruses were
determined as previously described by Graham and Prevec
(18). Briefly, pJM17, constituting the adenovirus genome,
was cotransfected with the pE1Asp1 shuttle vector containing the
full-length EID-1 cDNA into 293 cells with Lipofectamine (GIBCO/BRL).
Through homologous recombination, the EID-1 cDNA was integrated into
the adenovirus genome. Viruses were propagated on 293 cells and
purified using CsCl2 banding followed by dialysis against
phosphate-buffered saline (PBS) and 10% glycerol. Titers were
determined with 293 cells overlaid with Dulbecco's modified Eagle's
medium plus 5% equine serum and 0.5% agarose. The AdLacZ virus was a
gift from Frank Graham.
In vitro binding assays.
Expression of FLAG and glutathione
S-transferase (GST) fusion proteins was induced in BL21
cells with 0.2 mM isopropylthio--galactoside (IPTG). After 4 h,
the cells were pelleted and resuspended in PBS with 1 mM
phenylmethylsulfonyl fluoride, 1 µg of leupeptin per ml, 1 µg of
aprotonin per ml, and 1 µg of antipain per ml. Cells were lysed by
sonication and protein solubilized with 1% Triton X-100 for 30 min at
4°C. Cellular debris was removed by centrifugation. Proteins were
purified from the supernatant with glutathione-coated beads or
-FLAG-agarose.
The in vitro binding assays were performed by adding 5 to 10 µl of
[35S]methionine (Amersham) labeled, in vitro-transcribed
and -translated EID-1 or mutations (Promega) to 1 µg of GST or GST
fusion proteins in lysis buffer (150 mM NaCl, 50 mM Tris-HCl, 1 mM
EGTA, 1 mM NaF, 0.25% Na deoxycholate, 0.1% NP-40). Mixtures were
incubated for 1 h at room temperature and washed extensively with
lysis buffer. Bound complexes were resolved on a sodium dodecyl
sulfate-12% polyacrylamide gel (PAGE). The gels were dried, and
autoradiography was performed overnight.
Antibodies and protein identification.
Immunoprecipitations
were performed on total protein extracts prepared from L17 or U2OS
cells in LS buffer (PBS plus 0.1% NP-40) plus protease inhibitors. The
appropriate antibody was added, and the mixture was incubated for
11 h at 4°C. The bound proteins were collected for an additional
2 h with protein A/G-agarose and then washed four times with lysis
buffer. The bound complexes were resolved by PAGE and immunoblotting
was performed as previously described (7). Rb, recombinant
proteins, and markers of muscle differentiation were detected with
antibodies to Rb (Pharmingen), FLAG peptide (Kodak IBI), sarcomeric
actin (Sigma), -tubulin (Sigma), MyoD, Myf-5, myogenin, and p21
(Santa Cruz). Horseradish peroxidase-linked secondary antibodies were
purchased from Amersham.
Rabbits were immunized subcutaneously with a synthetic peptide
corresponding to the 15 C-terminal amino acids of EID-1,
RLTEELGCDEIIDRE, since this was the most highly conserved
domain across species, or ELYEESSDLQMDVMPGEG,
resulting in antibodies GN735 and GN431, respectively. Immune
serum was partially purified by affinity chromatography with the
corresponding peptide and used for Western blot analysis. Western
blotting was performed on total protein extracts from C2C12 cells
differentiated for the indicated time points, according to established
protocols (1).
Northern blot analysis.
A multiple-sample Northern blot
prepared from human tissue (Clontech) was probed using a
32P-labeled 350-bp probe spanning the N-terminal coding
sequences of human EID-1, by standard procedures (54). For
Northern blots involving adenovirus, C2C12 cells were infected with 50 PFU of virus per cell and allowed to differentiate for 72 h. Total
RNA was isolated and fractionated on a 1% denaturing agarose gel. The
-cardiac actin and -skeletal actin probes used to monitor muscle-specific gene expression and the glyceraldehyde-3-phosphate dehydrogenase probe used as a constitutive control have been previously described (48).
Flow cytometry.
EID-1 (20 µg) was transfected into CV-1
cells along with CMV-CD20 (5 µg), a lymphocyte cell surface marker,
at a ratio of 4:1 using Lipofectamine. Forty-eight hours after
transfection, cells were stained with a fluorescein isothiocyanate
(FITC)-labeled anti-CD20 antibody (Becton Dickinson) and analyzed by
two-color flow cytometry. DNA content in the successfully transfected
cells was quantified with propidium iodide as previously described
(24). Parallel transfections were performed with CMV-E2F-1
and CMV-p21.
p300 HAT assays.
p300 assays were performed according to
established protocols (23). Briefly, p300 complexes were
immunoprecipitated from U2OS lysates harvested in lysate buffer plus 10 mM Na butyrate. p300 was incubated with recombinant protein in the
presence of purified histones and [14C]acetyl coenzyme A
at 30°C for 30 min. Acetylated proteins were resolved on an SDS-15%
PAGE gel. Gels were fixed and incubated with Amplify (Amersham). Gels
were dried, and autoradiography was performed. In vivo p300 acetylation
assays were performed as described (23) using
3H-Na acetate on cardiac myocytes infected with 50 PFU of
the indicated virus per cell.
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RESULTS |
Interaction cloning of a novel, muscle-restricted, Rb-binding
protein.
pASRb, a yeast expression plasmid encoding aa 379 to
835 of Rb spanning the A-B and C pockets fused in frame to the GAL4 DNA-binding domain, was introduced into Y190. A single transformant was
isolated and cotransformed with a library of cDNAs derived from human
cardiac tissue and fused to the GAL4 activation domain (GAL4-AD).
Approximately six million transformants were screened, and DNA from the
initial HIS+ and LacZ-positive clones was purified for
further analysis. Reintroducing the isolated GAL4-AD chimeric proteins
into yeast along with pASRb or irrelevant GAL4-BD fusions revealed
that 22 clones reproducibly and specifically interacted with Rb. These
clones encoded nine unique proteins. Thirteen of the 22 clones encoded
four overlapping cDNAs for the same protein, called EID-1, which was
chosen for further study.
A consensus Kozak sequence was identified in frame with the GAL4-AD,
revealing an open reading frame predicted to encode a novel 187-aa
protein (Fig. 1A). Although the longest
cDNA cloned, which was 1.3 kb, was expected to contain the complete
open reading frame, analysis of mRNA suggested a transcript of 1.7 kb.
Therefore, we screened conventional phage-based libraries and
identified additional 3' untranslated sequences but no further coding
sequences, giving a complete cDNA of 1,638 nucleotides, which
correlates well with the observed mRNA. A search of GenBank using BLAST
did not reveal homology to any known proteins, although multiple
homologous clones were identified from the GenBank library of expressed
sequence tags and used to confirm the sequence. A search for potential functional motifs using the BLAST Enhanced Alignment Utility identified no known structural motifs. Analysis of the Human Gene Map maintained by the National Center for Biotechnology Information revealed the
corresponding human expressed sequence tag has been mapped to
chromosome 15q25.
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FIG. 1.
Sequence analysis of EID-1. (A) The predicted amino acid
sequence for EID-1. The LXCXE motif (shaded) and acidic domains
(underlined) are indicated. (B) Comparison of the aligned amino acid
sequence of the putative Rb-binding domain of EID-1 with the known
Rb-binding sites of BRG1, Elf-1, SV40 large T Ag, adenovirus E1A, and
HPV-16 E7 protein is shown. The conserved sequences in the consensus
EnLXCXE motif are shaded.
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Sequence analysis and homology searches did not reveal significant
similarity to any known proteins, as mentioned. However, within the C
terminus there was a consensus binding site for Rb (EXnLXCXE), which also is found in the Rb-binding domains
of simian virus 40 (SV40) large T antigen (Ag) (34), E1A
(13), human papillomavirus (28), and many
cellular Rb-binding proteins, such as BRG1, hBRM, Elf-1, and the
histone deacetylase, HDAC1 (68). Shown in Fig. 1B is the
amino acid sequence of this motif compared with those of other
Rb-binding proteins. The LXCXE motif of EID-1 and its surrounding
sequences was 100% conserved across human, mouse, and rat species
(data not shown), suggesting that this evolutionarily conserved domain
is critical for normal function. The exact LGCDE motif seen in EID-1
was previously isolated from a library of random peptides as an
Rb-binding peptide (75). This synthetic peptide sequence
represented one of only seven peptides capable of interacting with Rb
that were isolated from over three million transformants screened and
400 possible LXCXE combinations. This corroborates the specificity of
the LXCXE-Rb interaction, in concurrence with the observation that only
a small subset of all known proteins with LXCXE motifs has been
demonstrated to interact with Rb (5).
EID-1 expression is enriched in muscle tissues.
To investigate
the tissue distribution of EID-1, we probed a blot of
poly(A)+ RNA prepared from multiple samples of adult human
tissue. A single transcript was observed with an apparent size of 1.7 kb (Fig. 2A). As demonstrated, the
highest levels of EID-1 were found in cardiac tissue. Significant
expression was also seen in skeletal muscle and, to a lesser extent, in
brain tissue. Low levels of expression were observed in most tissues;
however, levels of expression in cardiac tissue are at least 10-fold
higher than those seen in lung or liver. Preferential expression of
EID-1 in adult striated muscle and brain likewise was seen in the mouse
(not shown).
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FIG. 2.
Expression analysis of EID-1. (A) Blots containing
poly(A)+ RNA from multiple samples of adult human tissue
were hybridized with the radiolabeled 350-bp human EID-1 cDNA. A single
1.7-kb transcript was detected. High-level expression was detected in
cardiac and skeletal muscle tissue. (B) Total RNA obtained from murine
ventricles at the indicated developmental time points or adult murine
atrial tissue was probed with a corresponding murine EID-1 probe. (C)
Protein extracts from primary human skeletal myotubes, differentiated
for the indicated times, were probed with polyclonal anti-EID-1
antibody (GN735) and antibodies to the indicated proteins.
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Since expression of EID-1 was highest in cardiac tissue, we sought to
determine the developmental expression and chamber specificity of EID-1
message. We prepared total RNA from murine ventricular tissue or from
adult atrial tissue at the indicated time points (Fig. 2B). EID-1 mRNA
abundance decreased with development in ventricular tissue while it
remained highly expressed in adult atrial tissue, explaining the high
levels of expression seen in the Northern blots of human tissue. To
determine the expression of EID-1 during skeletal-muscle
differentiation, protein extracts were prepared from primary cultures
of human skeletal myocytes cultured under differentiating conditions
(Fig. 2C). Using our affinity-purified polyclonal antibody generated
against the highly conserved C terminus of EID-1, a specific protein
product of 35 kDa was detected in differentiated human skeletal
myocytes (Fig. 2C). This is consistent with the size of EID-1
determined by in vitro transcription and translation and overexpression
of the cDNA in cultured cells (Fig. 3B;
see below). Levels of EID-1 protein decreased during myogenic
differentiation in contrast to that of muscle-specific -sarcomeric
actin. Equal levels of protein loading were confirmed by the uniform
expression of -tubulin. Therefore, EID-1 encodes a novel,
developmentally regulated, muscle-enriched protein.
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FIG. 3.
EID-1 interacts with Rb. (A) Yeast strain Y187 was
transformed with the EID-1-AD fusion protein and either the GAL4-BD
alone (pAS2) or indicated GAL4-Rb mutations. CPRG quantification of
-Gal activity was performed on six independent clones for each
transformation. (B) In vitro-transcribed and -translated
[35S]methionine-labeled EID-1 was incubated with 1 µg
of either GST, GST-Rb, or GST-Rb(H209). Complexes were precipitated
with glutathione-Sepharose beads and resolved by SDS-PAGE. (C) U2OS
cells were infected with the indicated virus and immunoprecipitated
with either preimmune or anti-EID-1 antibody (GN431).
Immunoprecipitates were probed with anti-Rb antibody.
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EID-1 interacts with Rb.
To confirm and further characterize
the domains in Rb necessary for interaction with EID-1, more-extensive
Rb deletional mutants were created. Deletion mutations were created
either by using convenient restriction sites or by PCR-based
mutagenesis. The respective constructs were subcloned into the yeast
GAL4-BD expression vector, pAS2, for use in the modified yeast
two-hybrid assay. Strength of interaction with EID-1 was quantified by
determining the LacZ activity in liquid cultures of plasmid-transformed
yeast (Fig. 3A). Results are expressed relative to activity in the
GAL4-BD alone. Although EID-1 interacts very weakly with the minimal
A-B pocket, consistent with the observation that this fragment of Rb
mediates interactions with LXCXE-containing peptides such as E1A and
SV40 large T Ag, high-affinity binding requires additional sequences
within the C pocket. In contrast, EID-1 did not interact either with
the B pocket alone or with full-length Rb containing a single amino
acid substitution at codon 706 (Cys to Phe) (ASH209) within the B
pocket, which is known to disrupt the binding of SV40 large T Ag (Fig.
3A). This corroborates the specificity of the EID-1-Rb interaction and
is consistent with the observation that EID-1 demonstrated no
interaction with any of the additional proteins tested (laminin C and
p53). As an additional test of the interaction between EID-1 and Rb, in
vitro binding assays were performed. In vitro-transcribed and
-translated, 35S-labeled EID-1 was incubated with the
indicated partially purified bacterially expressed GST fusion proteins.
Consistent with the result of the two-hybrid assays, EID-1 bound to
wild-type GST-Rb but was unable to bind a GST fusion protein containing
the pocket protein mutant of Rb described above (C706F) (Fig. 3B). To
confirm that EID-1 interacts with Rb in vivo, we infected U2OS
osteosarcoma cells with adenovirus overexpressing EID-1 or an
irrelevant protein, LacZ (Fig. 3C). Extracts were immunoprecipitated
with either preimmune or anti-EID-1 antibody and blotted for Rb. As
shown, only in cells infected with EID-1 was endogenous Rb coprecipitated.
EID-1 associates with Rb via its LXCXE motif, in vitro and in
vivo.
During the original library screening, one cDNA was isolated
that corresponded to an N-terminal deletion of EID-1 encoding only the
most C-terminal 80 aa. This suggested that the consensus LXCXE
Rb-binding motif located in this C-terminal fragment was a likely
candidate to mediate the Rb-EID-1 interaction. To confirm this, we
created a single amino acid substitution by site-directed mutagenesis
of EID-1, EID-1(C180G), which was predicted to disrupt Rb binding. This
conversion of LXCXE to LXGXE has been shown to render E1A incapable of
binding Rb (64).
In vitro binding assays were performed with in vitro-transcribed and
-translated wild-type EID-1 or EID-1(C180G).
[35S]methionine-labeled proteins were incubated with
bacterially produced GST or GST-Rb, and complexes were resolved on
polyacrylamide gels. As shown in Fig. 4A,
a single amino acid substitution in the LXCXE motif abrogated the
ability of EID-1 to interact with Rb. To confirm the specificity for
interaction between EID-1 and Rb in vivo, we tested the binding of
endogenous Rb to wild-type EID-1 versus the C180G mutation in
transfected mammalian cells. Figure 4B shows the results of
immunoprecipitation using anti-Rb antibody on total protein extracts
from transiently transfected L17 cells, expressing FLAG fusion proteins
of either EID-1 or EID-1(C180G). Immunoprecipitated complexes were
resolved by PAGE, and immunoblots were probed with an anti-FLAG
antibody. In a separate set of cultures, total extracts were probed
with anti-FLAG antibody to confirm that the wild-type and mutant EID-1
proteins were expressed at comparable levels. Similar to the results
seen in vitro, only wild-type EID-1 was able to associate with Rb.
These data confirm the interaction of EID-1 and Rb by independent,
complementary methods, implicating the LXCXE motif as the domain that
mediates this association as anticipated.
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FIG. 4.
EID-1 associates with Rb in mammalian cells. (A) In
vitro-transcribed and -translated [35S]methionine-labeled
EID-1 or EID-1(C180G) was incubated with 1 µg of either GST or
GST-Rb. Complexes were precipitated with glutathione-Sepharose beads
and resolved by SDS-PAGE. (B) L17 cells were transiently transfected
with FLAG epitope-tagged EID-1 or EID-1(C180G). Cell lysates were
immunoprecipitated with anti-Rb antibody, immunoprecipitates were
resolved by SDS-PAGE and analyzed by immunoblotting with anti-FLAG
antibody. Total cell lysates were immunoblotted with anti-FLAG antibody
to ensure the equivalent expression of proteins.
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EID-1 inhibits muscle-specific gene expression.
To determine
the effects of EID-1 on endogenous skeletal muscle-specific gene
expression, we used an adenovirus vector that overexpresses human EID-1
(AdEID-1) to uniformly infect C2C12 cells, a murine skeletal muscle
cell line. Undifferentiated myoblasts were infected with AdEID-1 or an
adenovirus vector expressing an irrelevant protein, AdLacZ, and allowed
to differentiate in low-serum medium for 72 h. Northern blot
analysis was performed on total RNA with the indicated probes, and RNA
from undifferentiated C2C12 cells was included for comparison. Relative
to levels seen in mitogenic serum (Fig. 4, lane 1), adenovirus delivery
of exogenous human EID-1 blocked the increase of skeletal -actin
mRNA completely and the increase of cardiac -actin mRNA by 51%
(Fig. 5A). In this myogenic cell line,
cardiac -actin is an earlier marker of differentiation than skeletal
-actin (3), suggesting that EID-1 was disproportionately
inhibiting later markers of differentiation. The human-specific EID-1
probe detected an appropriate increase in expression of human EID-1 in
AdEID-1-infected cells. Levels of glyceraldehyde-3-phosphate
dehydrogenase were similar in the three groups; thus, the effects of
EID-1 were selective to the differentiation-specific genes tested.
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FIG. 5.
EID-1 inhibits muscle-specific gene expression. (A) To
determine the effects of EID-1 on endogenous skeletal muscle-specific
gene expression, we used an adenovirus vector that overexpresses EID-1
(AdEID-1) to uniformly infect C2C12 cells, a murine skeletal muscle
cell line. Cells were infected with 50 PFU of AdEID-1 or AdLacZ per
cell and allowed to differentiate in low-serum medium (2% horse serum)
for 72 h. Northern blot analysis was performed of total RNA with
the indicated probes. RNA from undifferentiated C2C12 cells (in 20%
fetal bovine serum) was included for comparison. (B) To determine the
effects of EID-1 on MyoD family members, skeletal myoblasts were
infected with 5 or 50 PFU of AdEID-1 or AdLacZ per cell and allowed to
differentiate for 72 h. Protein extracts were probed with
polyclonal anti-EID-1 antibody (GN735) and antibodies to the indicated
proteins.
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Skeletal-muscle differentiation is a highly controlled process
involving the coordination of cell cycle exit and expression of
tissue-specific genes that is regulated by the hierarchical expression
of MyoD family members. To determine the effects of EID-1 on these
muscle-determining factors, we infected skeletal myoblasts with
differing amounts of EID-1 and characterized their expression (Fig.
5B). Levels of Myf-5, the functionally earliest member (52,
66), were unaffected by EID-1. MyoD expression was minimally
affected and only with the highest doses of EID-1. In contrast,
myogenin expression was inhibited by even the lowest doses of EID-1.
This data suggest that although EID-1 inhibits skeletal muscle
differentiation, the myogenic phenotype itself is not completely
reversed, since both Myf-5 and MyoD remained expressed. Genetic studies
with mice have confirmed the critical role of myogenin in skeletal
muscle development, particularly late aspects of myogenesis (25,
71). Interestingly, levels of p21 were not affected by EID-1,
which supports the lack of an effect of EID-1 on cell cycle progression
(see Fig. 8).
EID-1 inhibits MyoD-dependent transcription.
To confirm that
EID-1 was directly inhibiting muscle-specific transcription, we tested
its effect on a panel of skeletal muscle-specific promoters. As shown
in Fig. 6A, with primary skeletal muscle
cells transfected with EID-1 plus appropriate luciferase reporter
genes, EID-1 inhibits the transcription of both the skeletal -actin and the cardiac -actin promoter. Similar inhibition was seen with an
1,800-bp fragment of the muscle creatine kinase (MCK) gene, including
the MCK enhancer, which contains a canonical MyoD binding site (Fig.
6A).
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FIG. 6.
EID-1 inhibits muscle-specific gene expression. (A)
Primary cultures of skeletal myoblasts were transfected with SkA-Luc,
CaA-Luc, or MCK-Luc along with 1 µg of vector or CMV-EID-1. The
percent repression is compared to that of control cultures without
CMV-EID-1. (B) U2OS cells were transfected with EMSV-MyoD, 4RTk-luc,
CMV-LacZ, and increasing amounts of the CMV-EID-1 expression vector.
Results are shown relative to vector-transfected cultures. (C) Cells
were transfected as described along with 1 µg of vector, CMV-EID-1,
or EID-1(C180G). The fold induction is compared to control cultures
without EMSV-MyoD.
|
|
Since expression of skeletal muscle-specific genes is dependent on the
activity of MyoD or alternative MyoD family members, we determined the
effects of EID-1 on MyoD-dependent transcription in a heterologous
background (77). MyoD, along with a luciferase reporter
construct under the control of multiple MyoD binding sites, was
transfected into U2OS cells, and the effect of increasing amounts of
EID-1 was determined. As shown, EID-1 caused a dose-dependent reduction
in MyoD transcriptional activity (Fig. 6B). MyoD activity has been
reported to be dependent on the coexpression of Rb (44). Therefore, if MyoD transcriptional activity requires a direct interaction with Rb, one explanation for the observed effects of EID-1
might be that overexpression of any Rb-binding protein could
conceivably displace MyoD from the pocket, resulting in reduced
activity. To examine if EID-1's inhibition of MyoD-dependent transcription required an intact Rb-binding domain, EID-1(C180G) was
likewise tested for its effect on MyoD-dependent transcription (Fig.
6C). MyoD produced an 80-fold induction of the E-box reporter, which
was inhibited 65% by EID-1 (P < 0.0001) and 79% by
the Rb-binding mutant of EID-1 (P < 0.0001).
Surprisingly, the mutation that abolished Rb binding was a more potent
inhibitor of MyoD-dependent transcription than EID-1 at all doses
(P < 0.02). This strongly argues against the
possibility that EID-1 effects on skeletal muscle-specific
transcription are directly related to its ability to compete for Rb
pocket binding. Conversely, it suggests that pocket proteins normally
function to attenuate EID-1's inhibitory effects. These results raise
the possibility that EID-1 could exerts its effect on MyoD-dependent
transcription indirectly, by a mechanism distinct from interference
with Rb, perhaps by blocking the interaction of MyoD with other factors
that are critical for the full transcriptional activity of MyoD.
EID-1 inhibits MyoD-dependent transcription through multiple
domains.
To determine the domain or domains within EID-1
responsible for its inhibitory effects on MyoD-dependent transcription,
we created multiple-deletion mutations spanning the coding sequence of
EID-1 (Fig. 7). As demonstrated, neither
the C-terminal deletion (aa 122 to 187), the N-terminal deletion (aa 1 to 67), or the internal deletions singly or in combination (aa 53 to
61, 62 to 91, and 92 to 115) were able to completely block inhibition
by EID-1 (Fig. 7A and B). However, deleting the acidic domains in concert with the C terminus of EID-1 alleviated inhibition of MyoD
function (dl53dl92dl157; Fig. 7C and D) (42). In contrast, deleting the acidic domains in combination with the point mutation in
the LXCXE motif was not sufficient to relieve this inhibitory effect.
This implies that the C terminus interacts with factors or mediates
effects distinct from its association with Rb. Equal expression of all
constructs was confirmed by Western blotting (data not shown). These
data suggest that multiple domains within EID-1 contribute to its
inhibitory effects and that a block to MyoD function can be imposed by
either of the two regions alternatively.
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FIG. 7.
The C-terminal and acidic domains mediate inhibition of
MyoD-dependent transcription by EID-1. To determine the domain or
domains within EID-1 responsible for its inhibitory effects, we created
multiple-deletion mutations spanning the coding sequences of EID-1.
U2OS cells were transfected with 1 µg each of MyoD and 4Rtk-Luc and
indicated mutations as described below. Luciferase activity, corrected
for that of LacZ, is shown relative to expression in cells receiving
MyoD in the absence of EID-1. Amount of EID-1 vectors, 1 µg (A and C)
and 0.5, 1, or 2 µg (B and D).
|
|
Overexpression of EID-1 does not cause cell cycle reentry.
Many interventions that inhibit myogenic differentiation, such as
mitogens, E1A, and SV40 large T Ag, concomitantly provoke cell cycle
reentry. In skeletal muscle, substantial precedent has been established
for the pivotal role played in these reciprocal events by
developmentally regulated expression of cyclins, Cdks, and Cdk
inhibitors, especially G1 cyclins (21, 51, 63), although differing domains within Rb are now thought to mediate growth
control versus differentiation (58). Likewise, exogenous E2F-1 impairs both growth arrest and differentiation in skeletal and
cardiac muscle cells (31, 72). Therefore, repression of MyoD
activity could conceivably occur if overexpression of EID-1 resulted in
cell cycle progression with a concomitant increase in G1
cyclin activity or with the release of E2F from the pocket. Therefore,
to determine the effects of EID-1 on cell cycle progression, EID-1 was
transfected along with CMV-CD20, a lymphocyte cell surface marker, at a
ratio of 4:1 into CV-1 cells, a highly transfectable clonal cell line.
Successfully transfected cells were identified with a FITC-labeled
anti-CD20 antibody by flow cytometry, and DNA content was quantified
using propidium iodide (24). Parallel transfections with
E2F-1 and p21 were performed to demonstrate the fidelity of this
technique, where E2F-1 and p21 increase or decrease the percentage of
cells with DNA content greater than G0/G1,
respectively. As illustrated by a representative experiment (Fig.
8), EID-1 had no effect on G1
exit whereas E2F-1 and p21 evoked the expected responses. Similar
results were seen in independent studies, using adenovirus to express
EID-1 in ventricular muscle cells (data not shown). Thus, forced
expression of EID-1 had no discernable effects on cell cycle reentry in
either cell background.
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FIG. 8.
Overexpression of EID-1 does not cause cell cycle
reentry. To determine the effects of EID-1 on cell cycle progression,
vectors encoding EID-1, E2F-1, or p21 were transfected along with
CMV-CD20, a lymphocyte cell surface marker, at a ratio of 4:1 into CV-1
cells, a highly transfectable clonal cell line. Transfected cells were
identified with an FITC-labeled anti-CD20 antibody by flow cytometry,
and DNA content was quantified with propidium iodide.
|
|
EID-1 preferentially inhibits p300-dependent transcription.
Muscle-specific transcription is dependent on the actions of both
ubiquitous and cell type-specific transcription factors. Muscle-specific transcription factors such as MyoD (77) or
MEF2 (43) require interaction with p300 for full
transcriptional activity. Ubiquitously expressed factors, Sp-1 and YY1,
have been implicated in regulating skeletal and cardiac muscle-specific transcription both positively (22) and negatively (37,
40), respectively. However, their transcriptional activity has
been suggested to be p300 independent (2, 23). Therefore,
selective inhibition of p300-dependent transcription would account for
EID-1's preferential effect on tissue-restricted genes. To test
EID-1's effect on both p300-dependent tissue-restricted factors such
as MyoD or MEF2 or ubiquitously expressed p300-independent factors like
Sp-1 or YY1, EID-1 was cotransfected along with GAL4-BD fusion proteins
of these transcription factors into U2OS cells (Fig. 9A). EID-1 significantly inhibited MyoD
or MEF2 transcriptional activity while activity of Sp-1 or YY1 was
unaffected. To confirm that EID-1's inhibitory actions were p300
dependent, we cotransfected increasing amounts of p300 along with
EID-1. Overexpression of p300 rescued EID-1's inhibitory effects (Fig.
9B). These data support the concept that EID-1's inhibitory effects
are attributable to disrupting p300 function.
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FIG. 9.
EID-1 preferentially inhibits p300-dependent
transcription. (A) U2OS cells were transiently transfected with 1 µg
of GAL4-BD fusions of the indicated transcription factors with or
without CMV-EID-1. After 48 h, cell lysates were harvested and
luciferase activity was assayed and normalized to total protein.
Results are shown, relative to the levels of GAL4-BD fusion alone. (B)
To determine if overexpression of p300 could rescue EID-1's inhibitory
effects, U2OS cells were transiently transfected with EMSV-MyoD,
4RTk-luc, CMV-LacZ, and CMV-EID-1, along with increasing doses of
CMV-p300. After 48 h, cell lysates were harvested and luciferase
activity was assayed and normalized to LacZ activity.
|
|
EID-1 interacts with p300.
To test the ability of EID-1 to
interact with p300 in vivo, we performed immunoprecipitations with
lysates prepared from U2OS cells using an anti-EID-1 antibody (Fig.
10A). As shown, EID-1 immunoprecipitates specifically interacted with endogenous p300. To
determine the domains in p300 that mediated this association, we
performed in vitro binding assays utilizing
[35S]methionine-labeled EID-1 and bacterially expressed
GST fusion proteins spanning the entire p300 coding sequence. As shown
in Fig. 10B, EID-1 interacts with the C-terminal fragment of p300 corresponding to aa 1572 to 2370. This fragment contains the C-H3 domain, which has previously been shown to mediate p300's interaction with E1A (14) and MyoD (15, 77). To confirm that
EID-1 interacted with the C-H3 domain of p300 in vivo, U2OS cells were
transfected with GAL4-BD-EID-1 along with wild-type p300 or an
internal deletion mutant, p300dl30, removing residues 1738 to 1808, which are necessary for E1A and MyoD binding to the C-H3 domain (Fig.
10C). EID-1 was a weak transcriptional activator when fused to a
heterologous DNA-binding domain. Wild-type p300 further potentiated
EID-1-dependent transcription 7.6-fold. By contrast, the p300dl30
mutation, which retains full transcriptional activity (77),
does not potentiate transcription via the GAL4-BD-EID-1 fusion
protein, suggesting that the binding site for E1A, MyoD, and EID-1 all
map to this C-terminal domain of p300. Adenovirus E1A, an inhibitor of
muscle-specific gene expression, also transactivates transcription when
fused to a heterologous DNA-binding domain, which is further
potentiated by p300 (70). Superficially, this may seem
paradoxical, since E1A is known to inhibit p300-dependent HAT activity
(6). However, p300 is known to activate transcription by
multiple mechanisms (33), which might account for the
positive effect.
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FIG. 10.
EID-1 interacts with p300. (A) Total protein lysates
were prepared from U2OS cells, and EID-1-associated proteins were
immunoprecipitated with -EID-1 antibody. Complexes were resolved by
SDS-PAGE and probed with -p300 antibody. (B) In vitro-transcribed
and -translated [35S]methionine-labeled EID-1 was
incubated with 1 µg of either GST or the indicated GST-p300 fusion
proteins. Complexes were precipitated with glutathione-Sepharose beads
and resolved by SDS-PAGE. (C) U2OS cells were transiently transfected
with either 0.5 µg of GAL4-BD or GAL4-EID-1, 2 or 4 µg of CMV-p300
or CMV-p300del30, and a luciferase reporter gene under the control of
multiple GAL4-binding sites. After 48 h, cell lysates were
harvested and luciferase activity was assayed and normalized to that of
total protein. Results are shown relative to the amount of GAL4-BD
alone.
|
|
EID-1 inhibits p300 HAT activity.
To address the theoretical
possibility that EID-1, as a p300-binding protein, might merely
interfere with MyoD by sequestering this essential cofactor under
conditions of forced expression, we analyzed EID-1's effects on p300
function. Recently, several inhibitors of muscle-specific transcription
including E1A that interact with p300 have been shown to inhibit
p300-dependent HAT activity (6, 23). Therefore, to determine
if EID-1 also represses p300 HAT activity we performed in vitro
p300-dependent HAT assays in the presence of recombinant EID-1. As
shown in Fig. 11A, GST-EID-1 was a
potent inhibitor of p300-dependent HAT activity while GST alone had no
effect. To confirm EID-1's ability to inhibit p300-dependent HAT
activity, we ascertained its effect on p300's ability to autoacetylate itself in vivo with our recombinant adenovirus vectors. Cardiac myocytes were infected with AdEID-1 or AdLacZ, and the extent of
p300-dependent autoacetylation was determined. As shown, EID-1 was a
potent inhibitor of endogenous p300 HAT activity in vivo (Fig. 11B). To
clarify the domains within EID-1 that mediated this effect, we utilized
recombinant Flag-tagged EID-1 or indicated deletion mutants (Fig. 11C).
Wild-type EID-1 or deletion of the acidic domains (dl53dl92) or the
C-terminal deletion (dl157) retained the ability to inhibit p300 HAT
activity. In contrast, the compound deletion mutation (dl53dl92dl157)
that was incapable of inhibiting MyoD-dependent transcription had no
effect on p300 HAT activity. These data suggest that EID-1's
inhibitory properties are dependent on its ability to inhibit p300 HAT
activity.
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FIG. 11.
EID-1 inhibits p300 HAT activity. To determine if EID-1
inhibited HAT activity, immunoprecipitated p300 was incubated with
purified histones and [14C]acetyl coenzyme A. Complexes
were resolved by SDS-PAGE and subjected to autoradiography. (A)
Purified GST or GST-EID-1 was added to the indicated reaction
mixtures, and the effect on p300 HAT activity was determined. (B)
Cardiac myocytes were infected with the indicated viruses. Thirty-six
hours after infection, cells were exposed to 3H-Na acetate
for 1 h. Total protein lysates were harvested in lysate buffer
plus 10 mM Na butyrate, and p300 was immunoprecipitated. Shown are
autoradiograms documenting p300 autoacetylation in vivo. One-tenth of
the immunoprecipitated complexes was probed for total p300 expression
to ensure that results were not related to EID-1 effects on total p300
levels. (C) Purified Flag peptide or Flag fusion proteins (80 pmol)
were coincubated with the HAT assay mixture to determine the domains
within EID-1 that mediate this inhibitory effect.
|
|
| |
DISCUSSION |
In the present study, we have attempted to identify the factors in
striated muscle that interact with Rb. We have cloned a novel protein,
EID-1, expressed in cardiac and skeletal muscle that specifically
interacts with Rb through a LXCXE motif located in its C terminus.
Developmental expression patterns and overexpression studies of EID-1
suggested that this molecule represented a novel inhibitor of
differentiation. While in vitro binding studies and two-hybrid assays
strongly support the notion that EID-1 interacts with Rb, we have been
unable to directly show an interaction of the endogenous proteins. This
may be simply related to technical limitations of our reagents or the
low levels of expression of the two factors. Despite this, our data
suggest, at least indirectly, that the interaction of EID-1 with Rb is
functionally important. The point mutation in EID-1 that abolishes Rb
binding was a more potent inhibitor of MyoD-dependent transcription.
Therefore, our data support an alternative model for the interplay of
Rb and MyoD during skeletal muscle cell differentiation that would be dependent on the expression of Rb but does not require a direct Rb-MyoD
physical association. In support of this premise, data are presented in
the accompanying manuscript by Miyake et al. that not only can Rb
rescue EID-1's inhibitory effects but that overexpression of EID-1 can
disrupt some aspects of Rb function (42). EID-1 joins a
growing list of inhibitors of differentiation, including p202 and HBP1,
that have been shown to interact with Rb (10, 35). The fact
that several inhibitory factors have been identified which interact
with Rb suggests that this protein may represent a differentiation
checkpoint, linking factors regulating cell cycle exit and
tissue-specific gene expression (60).
Interestingly, Rb has also recently been shown to be critical for
MEF2-dependent transcriptional activity (45). This
potentiation of MEF2 activity was in part independent of Rb's effects
on cell cycle progression, but the basis of this cell cycle-independent effect was not determined. Since MEF2 transcriptional activity (55), like that of MyoD, has been reported to be p300
dependent, an indirect mechanism involving EID-1 might explain both the
defect in skeletal muscle gene expression in the absence of pocket
proteins (19, 44) and our and others' inability to confirm
a physical interaction between Rb and MyoD in vivo (45).
Additionally, it might explain the paradoxical observation that Rb can
potentiate the transcriptional activity of certain factors (8, 30,
62) despite its inherent transcriptional repressor-like activity
(59, 73). This link between Rb and p300 provides a cogent
hypothesis to explain these discordant results.
The similarities between EID-1 and E1A are obvious; however, several
differences are also apparent. The most obvious is EID-1's lack of
effect on cell cycle progression. A priori, based on results with
classic LXCXE proteins, E1A and SV40 large T Ag, one would have
predicted cell cycle reentry as the default hypothesis; however, there
are now multiple reports that endogenous cellular proteins with LXCXE
motifs can have divergent effects on the cell cycle (29,
50). This may in part be explained by the ability of pocket
proteins to bind multiple partners simultaneously (61). A
model for this regulatory activity has been proposed whereby Rb effects
on cell cycle are separable from its differentiation-promoting properties (58): Rb-dependent growth arrest requires an
intact E2F binding site, while E2F binding was dispensable for Rb to promote differentiation, suggesting that Rb was binding and modulating a second, functionally distinct class of proteins.
HATs play a critical role in tissue-specific transcription by relieving
repressive effects of chromatin condensation. p300 is a structural and
functional homologue of CREB-binding protein, a transcriptional
coactivator that not only has intrinsic HAT activity (46)
but is capable of recruiting additional HAT factors to the
transcriptional complex (76). p300, which was originally cloned as an E1A-binding protein, was subsequently shown to be critical
for normal skeletal muscle differentiation, since disruption of its
function by neutralizing antibodies or dominant-negative mutations
blocks both differentiation and cell cycle arrest (49, 55).
E1A mutations that selectively block p300 function are capable of
inhibiting skeletal and cardiac muscle differentiation (32,
41). Until recently, it was presumed that competitive binding was
the basis for the ability of E1A to inhibit tissue-restricted expression in skeletal muscle, since E1A interacts with the same region
of p300 as MyoD (C-H3 domain). However, E1A has now been shown to
directly inhibit the HAT domain of p300 or of the p300- and/or
CBP-associated factor, PCAF (6, 23). We have provisionally suggested an analogous mechanism for EID-1, whose interaction with p300
in two-hybrid assays was specifically contingent on the C-H3 domain
(Fig. 10C) and could inhibit p300 HAT activity (Fig. 11). Whether this
inhibition of HAT activity is a general model for differentiation
inhibitors will need to be determined; however, Twist, a skeletal
muscle inhibitor, has already been shown to interact with p300 and
inhibit its HAT activity (23).
In summary, our data suggest a novel mechanism for the interplay of Rb
and MyoD and for the dependence of skeletal muscle cell differentiation
on p300 and/or CBP. Further studies of EID-1 are in progress to
delineate whether EID-1 also directly effects MyoD, possibly by
inhibiting PCAF-dependent acetylation which has recently been shown to
be important for MyoD DNA binding and transcriptional activity
(56). Although EID-1 appears to be highly expressed in
striated muscle and brain tissue, its expression in adult tissues is
widespread, albeit at lower levels. Since Rb has been postulated to
play a role in the differentiation of a wide variety of tissues, EID-1
and the model proposed may represent a more generalized mechanism of
differentiation regulation. The extent of this role will await studies
detailing its developmental expression and the creation of a mouse
model deficient in this protein.
We thank T. Durfee, Y. Shi, and W. Kaelin for the indicated
plasmids, Frank Graham for the CMV.gal virus, and J. Kim and the
Baylor Flow Cytometry Lab for their technical assistance. We thank
Satoshi Miyake and Bill Kaelin for their discussions and for sharing
data prior to publication.
This work was supported by a gift from the Laubisch Fund and by NIH
grant K08 HL03671 to W.R.M. and NIH grants R01 HL47567 and R01 HL61668
to M.D.S.
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Abstract
Introduction
