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From the
Received for publication, November 13, 2001, and in revised form, February 26, 2002
The role of activating protein-1 (AP-1) in muscle
cells is currently equivocal. While some studies propose that AP-1 is
inhibitory for myogenesis, others implicate a positive role in this
process. We tested whether this variation may be due to different
properties of the AP-1 subunit composition in differentiating cells.
Using Western analysis we show that c-Jun, Fra-2, and JunD are
expressed throughout the time course of differentiation. Phosphatase
assays indicate that JunD and Fra-2 are phosphorylated in muscle cells and that at least two isoforms of each are expressed in muscle cells.
Electrophoretic mobility shift assays combined with antibody supershifts indicate the appearance of Fra-2 as a major component of
the AP-1 DNA binding complex in differentiating cells. In this context
it appears that Fra-2 heterodimerizes with c-Jun and JunD. Studying the
c-jun enhancer in reporter gene assays we observed that the muscle transcription factors MEF2A and MyoD can contribute to
robust transcriptional activation of the c-jun enhancer. In differentiating muscle cells mutation of the MEF2 site reduces transactivation of the c-jun enhancer and MEF2A is the
predominant MEF2 isoform binding to this cis element.
Transcriptional activation of an AP-1 site containing reporter gene
(TRE-Luc) is enhanced under differentiation conditions compared with
growth conditions in C2C12 muscle cells. Further studies indicate that
Fra-2 containing AP-1 complexes can transactivate the MyoD
enhancer/promoter. Thus, an AP-1 complex containing Fra-2 and c-Jun or
JunD is consistent with muscle differentiation, indicating that AP-1
function during myogenesis is dependent on its subunit composition.
The activating protein-1
(AP-1)1 transcription complex
is intrinsically involved in diverse cellular processes such as
transformation, apoptosis, proliferation, and differentiation (1). The
diverse cellular responses to AP-1 activity may, in part, be mediated by the specific subunit composition of the AP-1 complex. This complex
is a dimer of the Jun and Fos proto-oncogene families that binds to a
cis element termed the TRE
(12-O-tetradecanoylphorbol-13-acetate response
element) with the consensus 5'-TGAC/GTCA-3' (1). AP-1 is thus formed by
a dimeric association between Jun (c-Jun, JunB, and JunD) and Fos
(c-Fos, FosB, Fra-1, and Fra-2) family proteins or a subset of ATF
proteins. Therefore, a primary issue in understanding AP-1 activity
concerns the functional properties of the different AP-1 dimer
combinations. For example, in mouse fibroblasts JunD has an
antiproliferative role, whereas c-Jun promotes S-phase entry and
proliferation (2, 3). Furthermore, the role of AP-1 in apoptosis is
complex, dependent on the cellular context, and while c-Jun appears to
be pro-apoptotic, JunD protects cells from senescence and apoptosis
(4). Since AP-1 components are differentially expressed during
development and in different tissues, it is likely that heterogeneous
AP-1 complexes fulfill distinct roles in cells of different lineage.
This idea is supported by gene targeting experiments in which c-Fos
The process of muscle differentiation has proved to be a powerful model
for studying mechanisms of tissue-specific transcriptional control (17,
18). The identification and extensive characterization of the basic
helix-loop-helix myogenic regulatory factors (MRFs) and the
myocyte enhancer factor 2 (MEF2) transcription factors have led to the
establishment of a paradigm for the regulation of tissue specific gene
expression (17, 18). In contrast, the physiological role for AP-1
during myogenesis is not well defined. Initial studies showed that
c-Jun represses myogenesis due to a direct physical antagonism of the
activity of the MRF family members, MyoD and myogenin (19-21).
However, one hallmark of these studies was that the effects on
myogenesis were dependent on high levels of c-Jun overexpression from
retroviral vectors, possibly implying that the mechanism of inhibition
was through competition with the MRFs for a limiting factor such as
CBP/p300. Moreover, mice expressing an H-2K-v-Jun transgene develop
malignant sarcomas that contain focal areas of skeletal muscle (22).
These observations are consistent with the idea that expression
of v-Jun in transgenic tumors is compatible with skeletal muscle differentiation.
Since these studies, the full complexity of AP-1 has been documented,
and it is possible that c-Jun overexpression in these earlier
investigations disturbed the requirement for precise balance of AP-1
components in the cells. This idea is supported by observations that
AP-1 components can be detected in differentiating myogenic cells, and
some of the MRF gene promoters and certain muscle structural genes
contain TRE elements. Thus, co-expression of AP-1 proteins with
myogenic and structural proteins is compatible with a positive role for
physiological levels of AP-1 in myogenic differentiation (23-28).
Here, we report that the subunit structure of the AP-1 complex
undergoes a transition from a "proliferation"- to
"differentiation"-specific, Fra-2-containing complex during
myogenesis. Also, the transcriptional control of the c-jun
gene promoter becomes partially under the control of muscle specific
transcription complexes during differentiation. These data highlight
the complex role of heterogeneous AP-1 complexes in the context of
muscle cell differentiation.
Cell Culture--
HeLa and COS cells were grown in Dulbecco's
modified Eagle's medium (DMEM) with 10% fetal bovine serum (FBS) on
plastic dishes. C2C12 cells and primary rat myoblasts were grown in
DMEM + 10% FBS on gelatin-coated plastic dishes. To induce
differentiation of the C2C12 myoblasts or primary rat myoblasts, the
medium was changed to DMEM + 5% horse serum (as described previously
(29, 30)). For primary myoblast cultures, one litter of neonatal rat
pups was processed using standard procedures of trypsin/collagenase dissociation and preplating to deplete fibroblasts.
Immunoprecipitations and Immunoblotting--
Equal amounts of
protein per lane, as determined by Bradford assay, were resolved on
sodium dodecyl sulfate (SDS)-polyacrylamide gel (PAGE). Resolved
proteins were electrophoretically transferred to Nitroplus
nitrocellulose transfer membrane (Micron Separations). Membranes
were stained with Ponceau S to check for equivalent transfer and then
washed with 1× phosphate-buffered saline.
Membranes were blocked with 5% milk and then incubated overnight at
4 °C with primary antibody. Subsequently, the membranes were washed
three times with 5% milk and then incubated with horseradish peroxidase-conjugated secondary antibody at room temperature for 2 h. Excess secondary antibody was washed off by rinsing membranes in 5%
milk + 0.2% Nonidet P-40 two times and then 1× phosphate-buffered saline + 0.2% Nonidet P-40 three times. Western chemiluminescence reagent (PerkinElmer Life Sciences) was used to detect secondary antibodies on membranes (as described previously (30, 31)). Antibodies
used in these experiments were MyoD (SC304), c-Jun (SC1694), JunD
(SC74), and Fra-2 (SC604). The MEF2 antibodies used have been described
previously (29, 30, 33). Immunoprecipitations and phosphatase treatment
were performed as described previously (29, 31). The following
modifications were made to accommodate the Electrophoretic Mobility Shift Assays--
The DNA binding
assays and extract preparation were carried out as previously described
(29). Complementary oligodeoxyribonucleotides were synthesized with an
Applied Biosystems synthesiser. For the DNA binding assays with various
cell extracts, the incubation reaction contained equivalent amounts of
protein (based on a Bradford total protein assay), 0.2 ng of probe,
0.45 µg of poly(dI·dC), and 100 ng of single-stranded
oligonucleotide in a total volume of 20 µl. The bound fraction was
separated from the free probe by electrophoresis on a 4.5%
polyacrylamide gel (acrylamide:bis, 29:1) at 4 °C. The core
nucleotide sequences used in the binding assays were as follows:
c-jun MEF2, 5'-tcgagggctatttttagggcc and AP-1
5'-agcttgtgactcattt-3'. The underlined nucleotides
conform to the consensus sequence of the MEF2 site and AP-1 site,
respectively. For the immuno-gel shift analysis, where appropriate, 1 µl of antiserum or preimmune serum was added to the incubation
reaction. Where appropriate, antibody peptide competition was carried
out by preincubating the antibody with its peptide competitor prior to
inclusion in the binding reaction.
Transcriptional Response Assays--
For the reporter assays,
the appropriate reporter gene (see figure legends for details)
was transfected into C2C12 myoblasts and COS or HeLa cells, which were
at 60% confluence, by the calcium phosphate co-precipitation
technique. Each plate was transfected with 5 µg of the appropriate
luciferase reporter construct, and 2 µg of pSV
Expression of AP-1 Family Members during Myogenesis--
We
initially tested the expression of various AP-1 subunits in cultured
muscle cells. We found that both myoblasts and myotubes express c-Jun,
JunD, and Fra-2 (Fig. 1A).
MyoD expression was monitored in each immunoblot as an internal
control. Throughout the time course of differentiation, the expression
of c-Jun, JunD, and Fra-2 was maintained. There were some fluctuations
in the absolute levels of c-Jun, JunD, and Fra-2 by 120 h in
differentiation medium, but these were minor (Fig.
1A). Thus, we observed an appreciable expression of AP-1
factors throughout the time course of myogenic differentiation.
We observed at least two immunoreactive Fra2 and JunD bands in the
Western analysis, indicating the possibility of post-translational modification of these proteins by cellular signaling pathways during
differentiation (Fig. 1A). Immunoprecipitation of JunD and
Fra-2 followed by phosphatase treatment indicated that the major
isoforms of both proteins were altered in their mobility in SDS-PAGE,
indicating that they are phosphorylated in muscle cells (Fig.
1B). A number of signaling pathway-activated kinases are
known to target AP-1 proteins having both negative and positive effects
on AP-1 activity. Therefore, the precise implications of these
modifications for AP-1 activity in myogenic cells requires further
investigation. Even though the mobility of the JunD and Fra2 bands was
altered by phosphatase treatment, at least two immunoreactive bands
were still observed for each protein after phosphatase treatment (Fig.
1B). This indicates that these protein isoforms could result
from alternative splicing or another type of modification.
Heterogeneous Composition of AP-1 DNA Binding Complexes in
Proliferating Myoblasts and Differentiated Myotubes--
A major level
of control for AP-1 is at the level of heterodimer formation and DNA
binding activity; therefore we next assessed the contribution of the
different AP-1 family members to AP-1 DNA binding complexes in
myoblasts and myotubes. Since the similar molecular weight of the AP-1
proteins gives rise to similar sized DNA binding complexes, it is not
possible to discern heterogeneous complex composition by the mobility
of the binding complex alone. Therefore, to analyze AP-1 complex
composition, we used electrophoretic mobility shift assay analysis
coupled with specific antibodies against the AP-1 proteins. Fig.
2 indicates that in differentiating C2C12
myotubes the predominant dimer combination indicated by the immuno-gel
shift analysis was a Fra-2-containing complex, since nearly all of the
AP-1 complex was eliminated by antibodies directed against Fra-2. (Fig.
2B, lane 7). Since both c-Jun and JunD were also
in the complex (Fig. 2B, lanes 4 and
5), it is likely that the complex is comprised of
c-Jun:Fra-2 and JunD:Fra-2 heterodimers. In myoblasts, in contrast to
myotubes, there was virtually no Fra-2 in the complex (Fig.
2A, lane 7), although c-Jun and JunD are also
components of the AP-1 complex (Fig. 2A, lanes 4 and 5). Since c-Fos is expressed at high levels in
proliferating myoblasts (24), it is likely that the Jun partner in
myoblasts is c-Fos. However, we were unable to test this adequately due to the paucity of good c-Fos antibodies that work in electrophoretic mobility shift assay supershift analysis. Since Fra-2 is a major part
of the myotube AP-1 complex, we conclude that the major AP-1 complex in
differentiating myotubes is a JunD:Fra-2 or c-Jun:Fra-2 heterodimer.
Control of the c-Jun Promoter in Myogenic Cells--
Our studies
indicate that c-Jun expression is maintained in differentiating
myogenic cells despite the loss of growth factor signaling, which
normally regulates c-Jun transcription (32). Therefore, we went on to
analyze the c-jun enhancer/promoter in muscle cells to
discern whether muscle-specific transcriptional regulators could
contribute to its activation in the absence of "proliferative"
growth factor signaling. Previous studies have implicated the
transcriptional regulator MEF2 in the control of the c-jun
promoter in fibroblasts (33, 34). Since MEF2 is known to be induced
during muscle differentiation (35). We carried out a series of
experiments to test whether MEF2 is an important regulator of
c-jun transcription in myogenic cells. First, to determine
whether c-jun transcription could be activated by MEF2, HeLa
cells were transfected with the luciferase reporter pJLuc, which
contains Interaction between MEF2 and MyoD on the c-jun Enhancer--
It
has been demonstrated that the MEF2 and MRF transcriptional regulatory
proteins can physically interact to synergistically regulate
transcription (18). We therefore determined whether this synergistic
regulation could occur on the c-jun enhancer. To determine
this, HeLa cells were transfected with the luciferase reporter,
pJC90Fluc, which contains Activation of the c-jun Enhancer by Endogenous MEF2 Proteins during
Differentiation--
As MEF2 activity is critical for the myogenic
program and is induced when muscle cells differentiate, we next
determined the importance of the MEF2 site in the c-jun
enhancer during muscle differentiation. A C2C12 myoblast cell line or
primary myoblasts from neonatal rat pups were transfected with either
pJLuc, pJSX Luc, or p0Fluc. Serum was then withdrawn, and the cells
were placed in differentiation medium to initiate the
differentiation program, and reporter activity was determined. The
rationale being that since pJSX and pJLuc differ only in the mutated or
wild type MEF2 site, that any difference in reporter gene activity
would be due to this site. As can be seen in Fig. 3C (C2C12
cells) and Fig. 3D (primary myoblasts), the level of
reporter activity with pJSX Luc is significantly reduced compared with
the wild type promoter (pJLuc). Therefore, MEF2 activity contributes to
the regulation of the c-jun gene during muscle cell
differentiation. Overexpression of Fra-2 with the c-Jun promoter
indicated no effect of Fra-2 on the c-Jun enhancer activation (Fig.
3E).
Composition of the DNA Binding Complex at the MEF2 Site on the
c-jun Enhancer in Muscle Cells--
Since both MEF2A (present study),
and to a lesser extent, MEF2D (33), can activate the c-jun
enhancer, we wanted to find out which endogenous MEF2 proteins were
binding to this site in myogenic cells. This analysis showed that while
myoblasts contain virtually no binding activity on this
c-jun MEF2 site, as the cells begin to differentiate there
is a large increase in DNA binding to this cis element (Fig.
4A). The mobility of this
complex was equivalent to the complex produced by overexpression of
MEF2A in COS cells (Fig. 4A). To more specifically determine
which MEF2 proteins bind to the c-jun MEF2 site in muscle
cells, we used immuno-gel shift analysis with antibodies directed
against MEF2A, MEF2B, MEF2C, and MEF2D. These experiments indicate that
the major component of the binding complex is MEF2A, since an antibody
against this protein shifted the whole complex (Fig. 3B).
This is in agreement with our previous studies showing that MEF2A binds
to a similar site on the muscle creatine kinase enhancer (29). A small
fraction of the complex was shifted by the MEF2D antibody, indicating
that a small contribution of a MEF2A:MEF2D heterodimer to the MEF2 complex is also likely.
AP-1 Activity in Myogenic Cells and Activation of the MyoD
Promoter--
A role for AP-1 in muscle differentiation is supported
by recent observations that the MyoD and Myf5 promoters contain AP-1 elements (27, 23). We therefore tested what effect different AP-1
components have on the MyoD enhancer/promoter region. We studied the
2.5-kb MyoD promoter or the promoter plus the 258-bp core enhancer that
has recently been described (27) to determine whether AP-1 components
could transactivate these regions in transcriptional response assays.
These experiments indicated that Fra-2-containing AP-1 complexes could
activate transcription through the MyoD promoter region that contains
an AP-1 site (Fig. 5A),
although this requires further clarification by detailed promoter
analysis. Finally, we used an AP-1 site containing luciferase reporter
gene (TRE-Luc) to indicate the activity of AP-1 in C2C12 muscle cells
under growth and differentiation conditions. In these studies (Fig.
5B) we observed that despite the withdrawal of serum in
differentiation conditions, we could still see activation of the
TRE-Luc reporter gene, and the level of activation was greater than in
growth conditions. This, therefore, indicates that AP-1 activity is
maintained and potentiated under differentiation conditions in myogenic
cells.
Here we present data pertaining to the expression and activity of
AP-1 in myogenic cells. AP-1 activity in differentiating muscle cells
raises the possibility, contrary to previous ideas, that it may play a
positive role during myogenesis. Since the AP-1 complex in
proliferating myoblasts is distinct from that of terminally
differentiated myotubes, differentiation-specific changes in AP-1
composition may reflect dynamic changes in the activation of AP-1
target genes in these cells. In differentiating muscle cells the
predominant AP-1 complex consists of a heterodimer comprised of Fra-2
complexed with c-Jun or JunD. The increased level of Fra-2 in the
myotube AP-1 complex is correlated with cell cycle withdrawal and the
activation of muscle gene expression. Thus, these data suggest that a
different set of AP-1 target genes may be activated by heterogeneous
AP-1 complexes during differentiation. It is likely that there are a
multitude of AP-1 target genes in muscle, but one notable target could
be MRF family members. Here we show that Fra-2-containing AP-1
complexes can transactivate the MyoD core enhancer. Although the
functional implications of changes in the AP-1 subunit composition are
incompletely understood at this point, it is clear that the AP-1
complex in differentiating muscle cells is distinct from that in
proliferating myoblasts.
An important level of regulation of AP-1 occurs through controlling its
activity and concentration within the cell (1). For example the
activity of c-Jun and Fra-2 is regulated through phosphorylation (14,
36, 37). In response to various stressors such as UV, heat, or TNF- Activation of c-jun transcription through the
c-jun enhancer/promoter is elevated in growing HeLa cells.
We attribute this to the various sites in the enhancer, i.e.
NF-jun, jun1, jun2, SP1, and the CAAT
box, which are bound by various transcription factor complexes.
However, endogenous MEF2 proteins in HeLa do not contribute to this
activation, since the c-jun enhancer, which contains a
mutated MEF2 binding site, has the same activity as the wild type
enhancer when it is transfected. Therefore in HeLa cells, the basal
levels of c-jun transcription do not depend on the MEF2
site. In contrast to the minimal role played in proliferating cells, we
show that the MEF2 site in the c-jun enhancer is an important regulatory element in myogenic cells, since a mutated MEF2
site in the c-jun enhancer leads to a considerable
diminution of reporter activity during differentiation. The residual
enhancer activity remaining when the MEF2 site is mutated is due to the contribution from the other transcription factor binding sites or
possibly as yet unknown cis elements in the c-jun enhancer.
Previous studies have suggested that a putative AP-1/CRE element at
Considering our data, along with those of others, we propose a testable
model (Fig. 6) for the inclusion of
specific AP-1 complexes in a sub-circuit of the myogenic regulatory
hierarchy. In this model we propose that MEF2, which is strongly
induced during myogenic differentiation, activates c-Jun expression.
JunD/c-Jun dimerize with Fra-2 that becomes a major component of the
AP-1 complex in differentiating cells. Since Fra-2 is expressed
throughout the time course of differentiation, this change in Fra-2's
contribution to the AP-1 complex likely reflects post-translational
control of its DNA binding properties. Fra-2-containing AP-1 complexes can then target muscle genes and also contribute to the transcriptional activation of the MRFs. The MRFs are known to be able to induce MEF2
activity; and in the current study, we also present data suggesting
that one of the MRFs, MyoD, can affect the transcription of
c-jun through the MEF2 element, thus completing a
self-reinforcing feedback circuit. This model is based on data from the
current study and those of others (18, 23, 24, 28, 30, 32, 33).
Several studies in the early nineties suggested that AP-1 is inhibitory
for myogenesis because of the observation that overexpression of c-Jun
inhibits myogenesis due to a direct physical antagonism between the
leucine zipper of c-Jun and the helix-loop-helix domain of MyoD
(19, 20, 41). While the physical basis for the antagonism between the
two proteins when overexpressed is correct, based on our current data,
we contend that these observations have masked the role of endogenous
AP-1 in myogenic cells. A role for specific AP-1 complexes is not
without precedent having been implicated in cellular differentiation in
ovarian granulosa cells and osteoblasts (39, 40). The pleiotropic and
often contradictory functional role of AP-1 raises the question of how
can AP-1 mediate such contrasting processes? One possible explanation,
based on evidence presented by others and ourselves, is that
changes in the composition or phosphorylation of AP-1 subunits can
modulate its activity such that its target genes and biological
function are dynamically altered. We therefore propose that
physiological levels of an AP-1 complex consisting of a JunD/Fra-2 or a
c-Jun/Fra-2 heterodimer is consistent with, and not antagonistic to,
myogenic differentiation. We also show data indicating that AP-1 may
play a role in the full activation of MyoD expression due to direct
effects on the MyoD promoter. These data implicate specific AP-1
subunits in the positive control of muscle differentiation.
*
This work was supported by a grant from the NSERC of Canada
and the CIHR (to J. C. M.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, March 4, 2002, DOI 10.1074/jbc.M110891200
The abbreviations used are:
AP-1, activating protein-1;
TRE, 12-O-tetradecanoylphorbol-13-acetate response
element;
MRF, myogenic regulatory factor;
MEF, myocyte enhancer factor;
DMEM, Dulbecco's modified Eagle's medium;
FBS, fetal bovine
serum.
Composition and Function of AP-1 Transcription Complexes during
Muscle Cell Differentiation*
,,,,,, and
Department of Biology, York University,
Toronto, Ontario M3J 1P3, Canada, the § Department of
Biological Sciences, Columbia University, New York, New York 10027, and
the ¶ Department of Cell and Developmental Biology, University of
Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
/ mice have impaired bone development but are viable (5),
c-jun and junB knock-outs are lethal (6-8) and
targeted disruption of the junD gene results in specific
defects in male reproductive function (9). The importance of AP-1
composition for specific biological responses is also exemplified in
cellular transformation of NIH 3T3 by Ras; JunD is down-regulated in
contrast to c-Jun levels, which increase. Overexpression of JunD also
antagonizes transformation. The Jun proteins are responsive to an array
of stimuli such as UV irradiation, cytokines, oxidative stress, and
growth factors (1, 10-13). At least some of these signals are mediated
by activation of the JNK/SAPK kinase cascade (13-16). Thus, the
specific AP-1 dimer composition and also the targeting of these
components by cellular signaling pathways provide the cell with complex
machinery to modulate genes bearing this TRE element. Additional
studies to clarify the function of specific AP-1 dimers in different
cell types are therefore paramount to understanding the biology of AP-1
function in vivo, both during development and also in the adult.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
phosphatase
enzyme: after washing, the beads were suspended in phosphatase
buffer (50 mM Tris-HCl, pH 7.5, 0.1 mM
Na2 EDTA, 5 mM dithiothreitol, 0.01%
Brij 35) with 0.25 µl of phosphatase (400,000 units/ml; New
England Biolabs) and incubated for 30 min at 30 °C with gentle
shaking. The beads were then washed and boiled in SDS-PAGE buffer prior
to subsequent Western analysis.
-galactosidase, which served as an internal control for
transfection efficiency. For the overexpression studies, 2.5 µg of
pMT2-MEF2A and/or 6 µg of pMT2-MyoD, or the pMT2 vector alone as a
control, were transfected into the cells. Twenty-four hours later the
medium was changed to DMEM + 5% horse serum. For HeLa and COS
cell transfections, fresh DMEM + 10% FBS was added 48 h after the
calcium phosphate precipitate was added. The cells were then collected
24 or 48 h after the medium was changed. The reporter gene
constructs used were the following: pJ Luc, which contains 225 to
+150 of the c-jun enhancer/promoter upstream of a basal
promoter-luciferase gene (pGL2); pJSX Luc, containing 225 to +150 of
the c-jun enhancer/promoter (the same as pJLuc except for
two point mutations in the MEF2 site, which inhibit MEF2 binding); pJC6
contains 225 to +150 of the c-jun
enhancer/promoter upstream of a basal promoter-luciferase gene (this
contains the same regulatory elements as pJLuc except that a later
generation luciferase reporter gene was used as the backbone-pGL3);
pJTX (same as the wild type pJC6 apart from a point mutation in the AP-1 binding site); pJC90Fluc, which contains 80 to +150 of the c-jun enhancer, containing only the MEF2 and
jun1 site, upstream of 53 to +42 of the c-fos
promoter; p0FLuc, which contains 53 to +42 of the c-fos
promoter; and TATA Luc, which contains a TATA box upstream of the
luciferase reporter gene. A TRE-Luc reporter gene (1.5 µg) and 0.5 µg of pSV -galactosidase were transfected into myogenic
cells under growth and differentiation conditions as an indicator of
AP-1 activity. For these experiments, C2C12 cells were plated in
gelatin-coated six-well plates at a density of 2 × 105 cells/well. One day after plating, fresh FBS was added
to the growth condition prior to transfection. For the differentiation condition, 5% HS was added prior to transfection. On the day
following the transfection, the medium was changed to fresh 5%
horse serum for the differentiation condition. For the growth
condition, the cells were trypsinized and divided between two wells
prior to adding fresh 10% FBS. The cells in both conditions were
harvested 2 days after the transfection, and normalized luciferase
activity was determined. For the MyoD enhancer/promoter analysis we
used a luciferase reporter gene downstream of either the 2.5-kb MyoD promoter region or the 2.5-kb promoter region with the 258-base pair
core enhancer upstream (27). 2 µg of the reporter genes were
transfected along with 2 µg of the pCMV c-Jun, pCMV JunD, or pCMV
Fra-2 expression vectors. The cell extracts were prepared, and
luciferase activity was determined as described by the manufacturer (Promega).
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (51K):
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Fig. 1.
Expression of AP-1 components in myogenic
cells. C2C12 cells were harvested at 0, 3, 12, 24, 48, and
120 h after switching to differentiation medium
(DM). Cells were also collected after 3 h in growth
medium (GM) to control for possible effects of
switching the media that are not due to the differentiation stimulus.
All lanes were equally loaded. As an internal control the expression of
MyoD was monitored (upper panel). The second panel indicates
c-Jun immunoreactivity, the third indicates JunD, and the fourth shows
Fra-2 (A). In B JunD and Fra-2 were
immunoprecipitated from myoblasts and myotubes and either treated with
phosphatase (+) or not (). The immunoprecipitates were then
subjected to Western analysis to determine the mobility of the Fra-2
and JunD bands before and after phosphatase treatment. 1°
and 2° refer to the predominant immunoreactive bands for
Fra2 and JunD, respectively.
View larger version (52K):
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Fig. 2.
Composition of the AP-1 DNA binding complex
in myoblasts and myotubes. Extracts made from myoblasts or
myotubes were analyzed for the composition of AP-1 complexes. Where
indicated the extracts were preincubated with antibodies directed
against c-Jun, JunD, or Fra-2. In some cases the antibody was also
preincubated with a neutralizing peptide (pep.) inhibitor to
indicate antibody specificity. 50× refers to the inclusion
of a 50-fold molar excess of unlabeled AP-1 competitor in the binding
reaction.
225 to +150 of the c-jun enhancer upstream of the
firefly luciferase gene, with or without a pMT2 MEF2A expression vector. The results show that MEF2A overexpression leads to an increase
in luciferase activity indicating transcriptional activation of the
c-jun enhancer by MEF2A can occur (Fig.
3A). As a control, the
luciferase reporter p0Fluc, which consists of 53 to +42 of the
c-fos promoter, was not affected by MEF2A
overexpression.
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Fig. 3.
MEF2/MyoD complexes can activate the c-Jun
promoter. A shows the effect of overexpression of MEF2A
on the c-Jun promoter (pJLuc). p0Fluc is a basal promoter used as a
control. B shows the effect of expressing MyoD or MEF2 alone
or in combination on the c-jun enhancer. C and
D show the effect of mutating the MEF2 site in the
c-jun enhancer on the activation in C2C12 or primary rat
myoblast cells, respectively (the wild type enhancer is pJLuc, and the
mutated enhancer is pJSXLuc). E indicates the effect of
Fra-2 overexpression on the c-Jun promoter. pJC6 is the wild type
promoter, and pJTX contains the same promoter with the AP-1 site
mutated.
80 to +150 of the c-jun enhancer containing the MEF2 binding site. There is no E-box, the myogenic basic
helix-loop-helix binding site, in this region. p0FLuc was used as a
control. The reporters were transfected with either MEF2A, or MyoD
alone, or with MEF2A and MyoD together. pJC90FLuc along with MEF2A
alone led to approximately a 7-fold increase, while MyoD alone led to
about a 6-fold increase due to complexing with the endogenous MEF2
(Fig. 3B). Transfection of both MEF2A and MyoD together led
to approximately a 90-fold increase over pJC90FLuc alone. This is
7-fold the additive effect of MEF2A and MyoD transfected alone with
pJC90FLuc. These data indicate strong transcriptional synergy by MEF2
and MyoD in the control of the c-jun enhancer.
View larger version (74K):
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Fig. 4.
MEF2 binding to the c-jun
MEF2 site in muscle cells. Extracts were made from C2C12 as
myoblasts (MB) or after 2 (2d), 4 (4d), and 5 (5d) days after being switched to
differentiation media. On the left panel the MEF2 binding
complex is indicated (B). The fifth lane
indicates the binding of COS cell extracts, and the sixth
lane indicates the binding complex derived from COS cells
overexpressing MEF2A. On the right panel myotube extracts
were incubated with a preimmune (PI) serum (first
lane) or antibodies against MEF2A (A) (second
lane), MEF2B (B) (third lane), MEF2C
(C) (fourth lane), and MEF2D (D)
(fifth lane).
View larger version (16K):
[in a new window]
Fig. 5.
Activation of the MyoD promoter by AP-1
components. A, reporter gene assays were carried out
with the 2.5-kb MyoD promoter driving the luciferase reporter gene
(first through fifth bars) or the same vector with the
258-bp MyoD core enhancer upstream of the 2.5-kb promoter (sixth
through the tenth bars). As indicated the reporter genes were
co-transfected with JunD-, c-Jun-, or Fra-2-encoding expression vectors
(see "Experimental Procedures"). B, an AP-1 site
containing the reporter gene (TRE-Luc) was transfected into C2C12 cells
under growth and differentiation conditions, and the reporter activity
was measured after 2 days. GM, growth medium; DM,
differentiation medium.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
,
c-Jun is phosphorylated on Ser63 and, more prominently,
Ser73 in its activation domain by the JNKs (14, 16). This
phosphorylated c-Jun can then interact with co-activators CBP/p300 to
increase transactivation of target genes. The abundance of c-Jun is
also regulated at the level of protein stability. The half-life of c-Jun is ~90 min, and degradation of c-Jun has been shown to be mediated by the ubiquitin pathway (36). However, phosphorylation of
c-Jun by the JNKs decreases c-Jun ubiquitination and increases its
stability (36). Less is known concerning the regulation of Fra-2 by
phosphorylation, but the present study indicates that both JunD and
Fra-2 are modified by phosphorylation in myogenic cells. The
implications of this post-translational regulation of Fra-2 and JunD
during myogenesis is thus of considerable interest.
342 to 322 of the MyoD promoter is a negative regulator of MyoD
expression (38). This element is not a classical AP-1 site but fits the
consensus as a cAMP-responsive element. Previous studies suggest the
involvement of AP-1 in the regulation of this element. However, even
though c-Jun and c-Fos were implicated in negative control of the MyoD
promoter through this element, it is not yet known what the role of a
different AP-1 dimer combination could be. Our initial studies with
overexpression of Fra-2 indicate that it can activate the 2.5-kb MyoD
promoter containing this element, thus supporting the notion that there
could be differential regulation through this element depending on the
specific AP-1 dimer binding there. Additional studies of the MyoD gene
have indicated the presence of a consensus AP-1 site in the middle of a
region referred to as the MyoD core enhancer, which is located 20 kb
away from the transcriptional start site (27). Thus, further studies
dissecting the role of AP-1 dimer combinations on the MyoD promoter may
be important in determining the control of MyoD expression.
View larger version (13K):
[in a new window]
Fig. 6.
A schematic model integrating AP-1 components
into the myogenic cascade. MEF2 activates the transcription of the
c-Jun promoter. c-Jun/JunD dimerize with Fra-2. Fra-2-containing AP-1
complexes activate transcription of muscle structural genes and the MRF
genes. MRFs induce MEF2 activity closing a self-reinforcing feedback
loop. This model is constructed based on the data from the present
study and Refs. 18, 23, 24, 28, 30, 32, and 33.
FOOTNOTES
To whom correspondence should be addressed: 327 Farquharson
LSB, York University, 4700 Keele St., Toronto M3J 1P3. Tel.:
416-736-2100 (ext. 30389); Fax: 416-736-5698; E-mail:
jmcderm@yorku.ca.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1.
Angel, P.,
and Karin, M.
(1991)
Biochim. Biophys. Acta
1072,
129-157[Medline]
[Order article via Infotrieve] 2.
Pfarr, C. M.,
Mechta, F.,
Spyrou, G.,
Lallemand, D.,
Carillo, S.,
and Yaniv, M.
(1994)
Cell
76,
747-760[CrossRef][Medline]
[Order article via Infotrieve] 3.
Kovary, K.,
and Bravo, R.
(1992)
Mol. Cell. Biol.
12,
5015-5023 4.
Bossy-Wetzel, E.,
Bakiri, L.,
and Yaniv, M.
(1997)
EMBO J.
16,
1695-1709[CrossRef][Medline]
[Order article via Infotrieve] 5.
Grigoriadis, A. E.,
Wang, Z. Q.,
Cecchini, M. G.,
Hofstetter, W.,
Felix, R.,
Fleisch, H. A.,
and Wagner, E. F.
(1994)
Science
266,
443-448 6.
Hilberg, F.,
Aguzzi, A.,
Howells, N.,
and Wagner, E. F.
(1993)
Nature
365,
179-181[CrossRef][Medline]
[Order article via Infotrieve] 7.
Johnson, R. S.,
van Lingen, B.,
Papaioannou, V. E.,
and Spiegelman, B. M.
(1993)
Genes Dev.
7,
1309-1317 8.
Schorpp-Kistner, M.,
Wang, Z. Q.,
Angel, P.,
and Wagner, E. F.
(1999)
EMBO J.
18,
934-948[CrossRef][Medline]
[Order article via Infotrieve] 9.
Thepot, D.,
Weitzman, J. B.,
Barra, J.,
Segretain, D.,
Stinnakre, M.-G.,
Babinet, C.,
and Yaniv, M.
(2000)
Development (Camb.)
127,
143-153[Abstract] 10.
Angel, P.,
Hattori, K.,
Smeal, T.,
and Karin, M.
(1988)
Cell
55,
875-885[CrossRef][Medline]
[Order article via Infotrieve] 11.
Derijard, B.,
Hibi, M., Wu, I.-H.,
Barrett, T., Su, B.,
Deng, T.,
Karin, M.,
and Davis, R.
(1994)
Cell
76,
1025-1037[CrossRef][Medline]
[Order article via Infotrieve] 12.
Devary, Y.,
Gottlieb, R. A.,
Lau, L. F.,
and Karin, M.
(1991)
Mol. Cell. Biol.
11,
2804-2811 13.
Hibi, M.,
Lin, A.,
Smeal, T.,
Minden, A.,
and Karin, M.
(1993)
Genes Dev.
7,
2135-2148 14.
Karin, M.
(1995)
J. Biol. Chem.
270,
16483-16486 15.
Karin, M.,
Liu, Z.,
and Zandi, E.
(1997)
Curr. Opin. Cell Biol.
9,
240-246[CrossRef][Medline]
[Order article via Infotrieve] 16.
Kyriakis, J. M.,
Banerjee, P.,
Nikolakaki, E.,
Dai, T.,
Rubie, E. A.,
Ahmad, M. F.,
Avruch, J.,
and Woodgett, J. R.
(1994)
Nature
369,
156-160[CrossRef][Medline]
[Order article via Infotrieve] 17.
Davis, R. L.,
Weintraub, H.,
and Lassar, A. B.
(1987)
Cell
51,
987-1000[CrossRef][Medline]
[Order article via Infotrieve] 18.
Molkentin, J. D.,
Black, B. L.,
Martin, J. F.,
and Olson, E. N.
(1995)
Cell
83,
1125-1136[CrossRef][Medline]
[Order article via Infotrieve] 19.
Li, L.,
Chambard, J.,
Karin, M.,
and Olson, E. N.
(1992)
Genes Dev.
6,
676-689 20.
Bengal, E.,
Ransone, L.,
Scharfmann, R.,
Dwarki, V. J.,
Tapscott, S. J.,
Weintraub, H.,
and Verma, I. M.
(1992)
Cell
68,
507-519[CrossRef][Medline]
[Order article via Infotrieve] 21.
Grossi, M.,
Calconi, A.,
and Tato, F.
(1991)
Oncogene
6,
1767-1773[Medline]
[Order article via Infotrieve] 22.
Scuh, A. C.,
Keating, S. J.,
Yeung, M. C.,
and Breitman, M. L.
(1992)
Oncogene
7,
667-676[Medline]
[Order article via Infotrieve] 23.
Aurade, F.,
Pfarr, C. M.,
Lindon, C.,
Garcia, A.,
Primig, M.,
Montarras, D.,
and Pinset, C.
(1997)
J. Cell Sci.
110,
2771-2779[Abstract] 24.
Thinakaran, G.,
and Bag, J.
(1993)
Biochem. Cell Biol.
71,
260-269[Medline]
[Order article via Infotrieve] 25.
Thinakaran, G.,
Ojaia, J.,
and Bag, J.
(1993)
FEBS
319,
271-276[CrossRef][Medline]
[Order article via Infotrieve] 26.
Bishopric, N. H.,
Jayasena, V.,
and Webster, K. A.
(1992)
J. Biol. Chem.
267,
25535-25540 27.
Kucharczuk, K. L.,
Love, C. M.,
Dougherty, N. M.,
and Goldhamer, D. J.
(1999)
Development (Camb.)
126,
1957-1965[Abstract] 28.
Dorman, C. M.,
and Johnson, S. E.
(2000)
J. Biol. Chem.
275,
27481-27487 29.
Ornatsky, O. I.,
and McDermott, J. C.
(1996)
J. Biol. Chem.
271,
24927-24933 30.
Ornatsky, O. I.,
Andreucci, J. J.,
and McDermott, J. C.
(1997)
J. Biol. Chem.
272,
33271-33278 31.
Ornatsky, O. I.,
Cox, D. M.,
Tangirala, P.,
Andreucci, J. J.,
Quinn, Z. A.,
Wrana, J. L.,
Prywes, R., Yu, Y.-T.,
and McDermott, J. C.
(1999)
Nucleic Acids Res.
27,
2646-2654 32.
Lamph, W. W.,
Wamsley, P.,
Sassone-Corsi, P.,
and Verma, I. M.
(1988)
Nature
334,
629-631[CrossRef][Medline]
[Order article via Infotrieve] 33.
Han, T.,
and Prywes, R.
(1995)
Mol. Cell. Biol.
15,
2907-2915[Abstract] 34.
Han, T.,
Lamph, W. W.,
and Prywes, R.
(1992)
Mol. Cell. Biol.
12,
4472-4477 35.
Olson, E. N.,
Perry, M.,
and Schulz, A.
(1995)
Dev. Biol.
172,
2-14[CrossRef][Medline]
[Order article via Infotrieve] 36.
Musti, A. M.,
Treier, M.,
and Bohmann, D.
(1997)
Cell.
275,
400-402 37.
Murukami, M.,
Sonobe, M. H., Ui, M.,
Kabuyama, Y.,
Atanabe, H.,
Takahashi, A.,
Han, H.,
and Iba, H. E.
(1997)
Oncogene
14,
2435-2444[CrossRef][Medline]
[Order article via Infotrieve] 38.
Pedraza Alva, G.,
Zingg, J.-M.,
and Jost, J.-P.
(1994)
J. Biol. Chem.
269,
6978-6985 39.
Sharma, S. C.,
and Richards, J. S.
(2000)
J. Biol. Chem.
275,
33718-33728 40.
McCabe, L. R.,
Banerjee, C.,
Kundu, R.,
Harrison, R. J.,
Dobner, P. R.,
Stein, J. L.,
Lian, J. B.,
and Stein, G. S.
(1996)
Endocrinology
137,
4398-4408[Abstract] 41.
Su, H.,
Bos, T. J.,
Montecarlo, F. S.,
and Vogt, P. K.
(1991)
Oncogene
6,
1759-1766[Medline]
[Order article via Infotrieve]
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