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Molecular and Cellular Biology, February 2000, p. 1140-1148, Vol. 20, No. 4
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Extracellular Signal-Regulated Kinase Binds to
TFII-I and Regulates Its Activation of the c-fos
Promoter
Dae-Won
Kim and
Brent H.
Cochran*
Department of Cellular and Molecular
Physiology, Tufts University School of Medicine, Boston, Massachusetts
02111
Received 2 July 1999/Returned for modification 17 August
1999/Accepted 10 November 1999
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ABSTRACT |
We have previously shown that TFII-I enhances transcriptional
activation of the c-fos promoter through interactions with
upstream elements in a signal-dependent manner. Here we demonstrate
that activated Ras and RhoA synergize with TFII-I for c-fos
promoter activation, whereas dominant-negative Ras and RhoA inhibit
these effects of TFII-I. The Mek1 inhibitor, PD98059 abrogates the
enhancement of the c-fos promoter by TFII-I, indicating
that TFII-I function is dependent on an active mitogen-activated
protein (MAP) kinase pathway. Analysis of the TFII-I protein sequence
revealed that TFII-I contains a consensus MAP kinase interaction domain
(D box). Consistent with this, we have found that TFII-I forms an in
vivo complex with extracellular signal-related kinase (ERK). Point mutations within the consensus MAP kinase binding motif of TFII-I inhibit its ability to bind ERK and its ability to enhance the c-fos promoter. Therefore, the D box of TFII-I is required
for its activity on the c-fos promoter. Moreover, the
interaction between TFII-I and ERK can be regulated. Serum stimulation
enhances complex formation between TFII-I and ERK, and
dominant-negative Ras abrogates this interaction. In addition, TFII-I
can be phosphorylated in vitro by ERK and mutation of consensus MAP
kinase substrate sites at serines 627 and 633 impairs the
phosphorylation of TFII-I by ERK and its activity on the
c-fos promoter. These results suggest that ERK regulates
the activity of TFII-I by direct phosphorylation.
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INTRODUCTION |
TFII-I is a multifunctional protein
that appears to have functions in both transcription and signal
transduction. It was initially identified for its role in Inr-dependent
transcription (27, 44, 45) and has been also implicated in
E-box-dependent transcription (42, 43). Deletions of TFII-I
are tightly linked with Williams-Beuren syndrome, which is a
neurodevelopmental disease in humans (35). Recently, we and
others reported that TFII-I can bind to the serum response element
(SRE) and the c-sis/PDGF-inducible factor element (SIE) of
c-fos promoter and can also interact with serum response factor (SRF) (13, 24). We have also demonstrated that TFII-I can enhance the c-fos promoter in vivo in a manner that is
dependent on the upstream elements, including the SIE, the SRE, and
also its own binding sites, which overlap with the c-fos SIE
and SRE (24). Interestingly, TFII-I (BAP135) has been
identified as a factor which can form a complex with the Bruton's
tyrosine kinase (Btk) in B cells, and tyrosine phosphorylation of
TFII-I can be regulated by Btk (54). In addition, we have
previously shown that growth factor stimulation can enhance the
tyrosine phosphorylation of TFII-I and potentiate its enhancement of
c-fos promoter activation (24). These
observations suggest that TFII-I plays a role in signal transduction as
well as in transcriptional activation of the c-fos promoter.
The c-fos promoter is a very well studied immediate-early
gene promoter and responds rapidly and transiently to a variety of
extracellular stimuli (5, 12, 25, 31). Mechanisms for
responses to calcium, cyclic AMP, tyrosine kinases, mitogen-activated protein (MAP) kinases have been identified (4). Despite the fact that the c-fos promoter has been extensively
characterized, a number of important issues remain to be understood.
For instance, in order to respond to various MAP kinase cascades, SRF
can form a ternary complex at the c-fos SRE with various
ternary complex factors (TCFs), such as Elk-1. The TCF proteins are
substrates for MAP kinases and become transcriptionally active upon
phosphorylation (6, 19, 48, 50). However, there is
substantial evidence suggesting an alternative pathway which operates
through SRF independently of TCF (10, 21, 39). This pathway
is serum responsive and is mediated in part through the activation of
the small G protein RhoA (18). However, the mechanism of
activation of SRF by the Rho pathway has not been clearly established
(46), although there has been some evidence suggesting that
Rho kinase and the NF-
B and C/EBP transcription factors may be
involved (3, 30).
Moreover, there is a substantial synergism between elements of the
c-fos promoter (41). TFII-I interacts with both
STAT proteins and SRF, in addition to binding to the promoter at
positions that overlap with these sites (24). Thus, TFII-I
is well positioned to mediate synergism between these elements of the
promoter, although the mechanism of this synergism is not well understood.
TFII-I has only limited homology to other proteins, but it is
characterized by six helix-loop-helix repeats. Analysis of the primary
sequence of TFII-I also reveals a region of striking homology to the
consensus D box of Elk-1 (see Fig. 5A). The D box is a MAP kinase
interaction domain that was originally identified in the extracellular
signal-related kinase (ERK) substrate and c-fos transcription factor Elk-1 (52, 53). The same or similar
(
domain) motifs can be found as MAP kinase docking sites in several MAP kinase interacting transcription factors (7, 20, 22, 23,
51). Moreover, TFII-I also contains putative MAP kinase phosphorylation sites which are very similar to those found in Elk-1 as
shown in Fig. 10A (16, 29). This suggests that TFII-I, like
Elk-1, may also interact with ERK and be phosphorylated by it.
To understand the regulation of TFII-I by signal transduction pathways,
we report here that TFII-I can be regulated by Ras and Rho pathways and
that it requires a functioning ERK pathway for the activity. We also
demonstrate that TFII-I can interact with the MAP kinase ERK1 through
its consensus MAP kinase binding domain (D box) and that this
interaction is required for its activity on the c-fos
promoter. Moreover, the interaction between TFII-I and ERK can be
regulated by signal transduction pathways. In addition, we show here
that TFII-I can be a direct substrate for ERK and that the consensus
ERK phosphorylation sites of TFII-I are required for its activity.
These results suggest that TFII-I functions as a regulated signaling
molecule for the activation of the c-fos promoter.
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MATERIALS AND METHODS |
Plasmids and antibodies.
For transient overexpression of
human TFII-I, pEBG-TFII-I construct was used as previously described
(2, 24). The wild-type c-fos-luciferase
construct and pRL-TK luciferase construct for reporter assays were as
previously described (24). Activated or dominant-negative
Ras, Rac1, Cdc42h, or RhoA expression plasmids were as previously
described (8, 9, 32, 36, 37). BXB-Raf and HA-ERK1 expression
plasmids were also as previously described (11, 40). Mek1/EE
expression plasmid was purchased from Stratagene, and pCDNA3 empty
vector was obtained from Invitrogen. Anti-TFII-I polyclonal rabbit
antisera was made against the purified recombinant glutathione
S-transferase (GST) fusion protein containing C terminal 389 amino acids of human TFII-I. Anti-ERK1 antibody was obtained from Larry
Feig. The anti-GST antibody was obtained from Sigma and the
anti-hemagglutinin (HA) antibody was obtained from Boehringer Mannheim.
Anti-phosphoERK antibody was obtained from New England Biolabs.
Cell culture and transfections.
Murine NIH 3T3 fibroblasts
were grown in Dulbecco modified Eagle medium (DMEM) with 10% calf
serum (CS). COS-1 cells were cultured in DMEM with 10% fetal calf
serum (FCS). For transient transfection, the calcium phosphate
transfection kit from 5 Prime 3 Prime Co. was used. For reporter
assays, NIH 3T3 cells were maintained for 30 to 40 h in medium
containing 0.5% CS following transfection and stimulated with 10% FCS
where indicated for 3 to 4 h before harvest. One hundred nanograms
of reporter construct, 250 ng of pEBG-TFII-I (or pEBG) expression
plasmid, and 25 ng of pRL-TK normalization plasmid were used per single
well of a 12-well plate. Twenty-five nanograms of various small G
proteins, BXB-Raf, or Mek1/EE expression plasmid was included where
indicated. The total amount of DNA per well was kept at 400 ng by using
pCDNA3 to adjust total DNA amounts where necessary. Dual luciferase
assay was carried out as previously described (24). All
transfection experiments were performed in duplicate, and results were
normalized to the expression of the renilla luciferase transfection
control. For inhibitor treatment, transfected NIH 3T3 cells were
incubated with 100 nM PP1 (15), 100 nM wortmannin
(34), or 25 µM PD98059 (1) for 1 h prior
to 10% FCS stimulation, and the inhibitors were also included during
serum stimulation. For Fig. 9, 25 µM PD98059 (1) or
SB202190 (26) was added to the transfected COS-1 cells
1 h before harvest. PP1, wortmannin, PD98059, and SB202190 were
obtained from Calbiochem. For protein-protein interaction assays, COS-1
cells were maintained before harvest for 36 h in medium containing
10% FCS following transfection. Five micrograms of pEBG, pEBG-TFII-I,
pEBG-L289A-TFII-I, or HA-ERK, along with 2.5 µg of N17-Ras,
N17-Rac, or N19-Rho construct, was used per 100-mm plate. The total
amount of DNA was kept at 12.5 µg per 100-mm dish by using pCDNA3 to
adjust total DNA amounts where necessary. For Fig. 7, NIH 3T3
fibroblasts were serum starved for 36 h with 0.5% CS and
stimulated with 15% FCS for 10 min before harvest.
GST pulldown, immunoprecipitation, and Western blot
analysis.
Cell lysates were prepared in buffer containing 20 mM
Tris (pH 7.8), 200 mM KCl, 10% glycerol, 0.4% Triton X-100, 0.5 mM
phenylmethylsulfonyl fluoride (PMSF), and 1 µg each of leupeptin,
antipain, pepstatin, and chymostatin per ml except in Fig. 10B. The
lysates were then centrifuged for 10 min at 10,000 × g
at 4°C, and the supernatants were used for GST pulldown or
immunoprecipitation assays as previously described (24).
Western blot analyses were carried out under standard conditions.
In vitro mutagenesis and isolation of overexpressed TFII-I.
L289A-TFII-I, S627A-TFII-I, or S633A-TFII-I mutant was generated
according to the manufacturer's protocol provided with the QuickChange
Site-Directed Mutagenesis Kit from Stratagene. The following
complementary oligonucleotides were used to synthesize mutated DNA
strands: L289A (+),
CCGTCTAAGAGACCAAAGGCCgcTGAGgcACCGCAGCCACCAGTCCCG; L289A
(
), CGGGACTGGTGGCTGCGGTgcCTCAgcGGCCTTTGGTCTCTTAGACGG;
S627A (+),
GGCTAGTAAAATAAACACTAAAGCTTTGCAGgCtCCCAAAAGACCACGAAGTCC;
S627A (),
GGACTTCGTGGTCTTTTGGGaGcCTGCAAAGCTTTAGTGTTTATTTTACTAGCC;
S633A (+), GCAGTCCCCCAAAAGACCACGAgcTCCTGGGAGTAATTCAAAGGTTCC;
and S633A (),
GGAACCTTTGAATTACTCCCAGGAgcTCGTGGTCTTTTGGGGGACTGC. The
wild-type or various mutant TFII-I proteins were purified from
transfected COS-1 cells as previously described (24), and an
equal amount of each protein was used for in vitro kinase assays.
In vitro kinase assay.
For Fig. 10B, 10 µg of HA-ERK
expression construct per 100-mm plate was transfected into COS-1 cells,
and the cells were maintained for 36 h in medium containing 10%
FCS and then stimulated with 25 ng of epidermal growth factor (EGF) per
ml for 10 min before harvest. Cell lysates were prepared in the buffer
containing 25 mM Tris (pH 7.5), 100 mM NaCl, 10 mM MgCl2, 5 mM MnCl2, 0.2 mM Na3VO4, 10%
glycerol, 1% Triton X-100, 0.5 mM PMSF, and 1 µg each of leupeptin,
antipain, pepstatin, and chymostatin per ml. The lysates were then
centrifuged for 10 min at 10,000 × g at 4°C, and the
supernatants were used for anti-HA antibody immunoprecipitation. Immunoprecipitated ERK containing beads were washed with kinase buffer
(25 mM Tris [pH 7.5], 100 mM NaCl, 10 mM MgCl2, 5 mM
MnCl2, 0.2 mM Na3VO4). The immune
complex kinase assay was performed essentially as described previously
(47). Briefly, immunoprecipitates were incubated with 20 µCi (6,000 Ci/mmol) of [
-32P]ATP either in the
presence or the absence of substrate proteins for 30 min at room
temperature. The labeled proteins were then separated on by sodium
dodecyl sulfate (SDS)-8% polyacrylamide gel electrophoresis (PAGE),
fixed, dried, and visualized by autoradiography.
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RESULTS |
Ras and Rho pathways can regulate the activity of TFII-I.
To
investigate the functional relationship between various small G protein
signal transduction pathways and TFII-I, the effects of Ras, Rac1, and
RhoA on the activity of TFII-I were examined. To do this,
constitutively activated V12-Ras, L61-Rac, or L63-Rho were transfected
into NIH 3T3 fibroblasts with the c-fos-luciferase reporter
in the absence or presence of TFII-I, and luciferase activity was
measured. The cells were maintained in low-serum medium after
transfection. As shown in Fig. 1, without
serum or growth factor stimulation, the activated V12-Ras and L63-Rho
efficiently synergized with TFII-I for c-fos promoter
activation, whereas activated L61-Rac showed only weak effects. These
results suggest that the Ras and Rho pathways are more important for
the effects of TFII-I on the c-fos promoter than is the Rac
pathway.
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FIG. 1.
V12-Ras and L63-Rho synergize with TFII-I for the
c-fos promoter activation. The V12-Ras, L61-Rac, or L63-Rho
expression plasmid was transfected into NIH 3T3 fibroblasts with the
c-fos-luciferase reporter construct in the absence or
presence of TFII-I, and the cells were maintained for 40 h in
0.5% CS before harvest. Cell extracts were then processed for
luciferase activity. The relative luciferase activities shown here are
from a representative experiment, and similar results were obtained
from three further independent experiments. All transfections were
performed in duplicate for each experiment, and the values between the
duplicates were within 10% of the mean.
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To further evaluate the functional cooperation between various small G
protein pathways and TFII-I, we transfected dominant-negative
N17-Ras,
N17-Rac1, N17-Cdc42, or N19-RhoA into NIH 3T3 fibroblasts
with the
c-
fos-luciferase reporter in the absence or presence
of
TFII-I, and the luciferase activity was measured after serum
stimulation. As can be seen in Fig.
2,
all of the dominant-negatives
decreased overall activity of the
c-
fos promoter but to different
degrees. However, only the
dominant-negative N17-Ras and N19-Rho
completely eliminated the ability
of TFII-I to enhance the c-
fos promoter in response to serum
stimulation. The dominant-negative
N17-Rac and N17-Cdc42 had only
partial effects. Dose-response
experiments indicated that the
inhibitory effects of N17-Rac and
N17-Cdc42 on TFII-I were nearly
maximal at the amounts used in
these experiments and that even
20-fold-higher doses fail to inhibit
completely (data not shown).
Consistent with the results from
Fig.
1, these results also indicate
that the Ras and Rho pathways
are more significant for the activity of
TFII-I than Rac or Cdc42.
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FIG. 2.
N17-Ras and N19-Rho inhibit TFII-I enhancement of the
c-fos promoter. NIH 3T3 cells were transfected with the
c-fos-luciferase reporter construct and pEBG-TFII-I (or
pEBG) plasmid in the presence of pCDNA3, N17-Ras, N17-Rac, N17-Cdc42,
or N19-Rho plasmid. Cells were serum starved for 36 h in 0.5% CS
and stimulated for 4 h with 10% FCS. Cell extracts were then
processed for luciferase activity. Relative luciferase activities shown
here are from a representative experiment, and similar results were
obtained from three further independent experiments. All transfections
were performed in duplicate for each experiment, and the values between
the duplicates were within 10% of the mean.
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Since Ras efficiently synergized with TFII-I, we sought to determine
whether the downstream kinases of the Ras-ERK pathway
are capable of
cooperating with TFII-I. A cotransfection assay
similar to that in Fig.
1 was carried out with activated BXB-Raf
or Mek1/EE. Results are shown
in Fig.
3. TFII-I overexpression
was able
to enhance c-
fos promoter activation with either BXB-Raf
or
Mek1/EE, suggesting that the Ras/MAP kinase pathway is specifically
able to functionally cooperate with TFII-I. The effector of RhoA
leading to the activation of the c-
fos SRE has not been
clearly
identified yet (
46).
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FIG. 3.
BXB-Raf and Mek1/EE cooperate with TFII-I for
c-fos promoter enhancement. BXB-Raf or Mek1/EE expression
plasmids were transfected into NIH 3T3 fibroblasts with the
c-fos-luciferase reporter construct in the absence or
presence of TFII-I, and cells were maintained for 40 h in 0.5% CS
before harvest. Cell extracts were then processed for luciferase
activity. Relative luciferase activities shown here are from a
representative experiment, and similar results were obtained from three
further independent experiments. All transfections were performed in
duplicate for each experiment, and the values between the duplicates
were within 10% of the mean.
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Functional MAP kinase pathway is required for the activity of
TFII-I.
To further explore the functional relationship between
different signal transduction pathways and TFII-I, we examined the effect of various kinase inhibitors on the activity of TFII-I. PP1, a
specific inhibitor for Src family kinases (15), wortmannin, a specific inhibitor for PI-3-kinase (34), or PD98059, a
specific inhibitor for Mek1 (1), were used in the reporter
assay. The c-fos-luciferase reporter construct was
transfected into NIH 3T3 fibroblasts in the absence or presence of
TFII-I, and the three different inhibitors were preincubated prior to
serum stimulation. Luciferase assay was carried out after serum
stimulation. As can be seen in Fig. 4,
none of these specific inhibitors dramatically decreased the overall
activity of the c-fos promoter. Since a number of different
pathways can cooperate to induce c-fos, specific inhibition
of a single pathway may not be sufficient to inhibit the overall
promoter response. Nevertheless, the enhancement of the
c-fos promoter by TFII-I was completely abolished by Mek1 inhibitor PD98059, which blocks ERK activation. This result suggests that TFII-I functions in a manner that is dependent on a functionally intact MAP kinase pathway. PP1 and wortmannin did not have significant effects on the activity of TFII-I, indicating that Src kinase and
phosphatidylinositol 3-kinase pathways are not necessary for TFII-I
potentiation of the c-fos promoter.
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FIG. 4.
PD98059 abolishes the activity of TFII-I on the
c-fos promoter. NIH 3T3 cells were transfected with the
c-fos-luciferase reporter construct in the absence or
presence of TFII-I and serum starved for 36 h in 0.5% CS
following the transfection. The transfected cells were then incubated
with 100 nM PP1, 100 nM wortmannin, or 25 µM PD98059 for 1 h
prior to serum stimulation. Each inhibitor was also included during
4 h FCS stimulation. Cell extracts were then processed for
luciferase activity. The relative luciferase activities shown here are
from a representative experiment, and similar results were obtained
from three further independent experiments. All transfections were
performed in duplicate for each experiment, and the values between the
duplicates were within 10% of the mean.
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TFII-I can form a complex with ERK.
Since the Ras/MAP kinase
pathway is important for the activity of TFII-I, we sought to determine
whether TFII-I might directly bind to ERK. Interestingly, sequence
comparison of TFII-I with other known MAP kinase binding proteins
reveals a striking homology between one region of TFII-I and known MAP
kinase interaction domains (D box), as shown in Fig.
5A. Thus, GST or GST-TFII-I expression
plasmids were cotransfected with an HA-ERK expression plasmid into
COS-1 cells to detect in vivo interaction between TFII-I and ERK.
Protein complexes were isolated by GST pulldown, and the resulting
complexes were separated by SDS-PAGE and analyzed by Western blotting
by using anti-HA antibody. As can be seen in Fig. 5B, significant
complex formation was observed between TFII-I and ERK (subpanel
A, lane 2), whereas no interaction was detected between GST and ERK
(subpanel A, lane 1). Figure 5B, subpanel B, shows that there
were comparable levels of expression of the transfected ERK between the
samples in this experiment.
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FIG. 5.
TFII-I forms a complex with ERK. (A) A consensus MAP
kinase interaction domain (D box) of TFII-I (53). (B) TFII-I
can form an in vivo complex with the MAP kinase, ERK1. HA-ERK1
expression plasmid was cotransfected into COS-1 cells with pEBG (lane
1) or pEBG-TFII-I (lane 2) expression plasmid. Transfected COS-1 cells
were lysed and subjected to GST pulldown assay. Glutathione-Sepharose
bead-bound proteins (A) and total extracts (B) were fractionated by
SDS-12% PAGE and analyzed by anti-HA antibody Western blotting.
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The D box of TFII-I is required for its interaction with ERK and
activation of c-fos promoter.
To further characterize
the interaction between TFII-I and ERK, we asked whether the TFII-I D
box is required for its interaction with ERK. To do this, N287 and L289
(residues marked in Fig. 5A) of TFII-I were changed to alanines to
disrupt the consensus motif for MAP kinase interaction as previously
described with Elk-1 (52, 53). This mutant henceforth is
referred to as L289A-TFII-I. The non-PCR-based QuickChange
mutagenesis method (Stratagene) was used for mutagenesis to avoid
introduction of other mutations into the protein, and the mutation was
verified by sequencing. To compare ERK binding capability between the
wild-type and the mutant TFII-I, GST-fused wild-type-TFII-I or
L289A-TFII-I expression plasmids were cotransfected with HA-ERK
expression plasmid into COS-1 cells. GST pulldown assay and Western
blotting with anti-HA antibody were carried out to determine the
interaction between the mutant L289A-TFII-I and ERK. As can be seen in
Fig. 6A, the mutant L289A-TFII-I
completely lost its ability to form a complex with ERK (lane 2 [subpanel A]) compared to the wild-type TFII-I (lane 1 [subpanel
A]). Subpanel B shows that there was comparable expression of the
transfected ERK between samples, and subpanel C confirms the expression
of the transfected L289A-TFII-I (lane 2). These results clearly
indicate that the putative MAP kinase binding motif (D box) found in
TFII-I is necessary for the interaction with ERK.
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FIG. 6.
The D box of TFII-I is required for its interaction with
ERK and activation of the c-fos promoter. (A) An intact
TFII-I D box is required for ERK interaction. pEBG-TFII-I (wild type)
(lane 1) or pEBG-L289A-TFII-I (lane 2) expression plasmid was
cotransfected with HA-ERK expression plasmid into COS-1 cells.
Transfected COS-1 cells were lysed and subjected to GST pulldown assay.
Glutathione-Sepharose bead-bound proteins (A and C) and total extracts
(B) were fractionated by SDS-12% PAGE and blotted by use of anti-HA
(A and B) or anti-GST (C) antibody. (B) TFII-I requires ERK interaction
for its enhancement activity on the c-fos promoter. pEBG,
pEBG-TFII-I (wild type), or pEBG-L289A-TFII-I plasmid were
transfected into NIH 3T3 fibroblasts with the
c-fos-luciferase reporter construct. Cells were serum
starved for 36 h in 0.5% CS and then stimulated for 4 h with
10% FCS. Cell extracts were then processed for luciferase activity.
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Next we examined whether the D box of TFII-I is required for its
activity. L289A-TFII-I was transfected into NIH 3T3 fibroblasts
with
the c-
fos-luciferase reporter construct, and the luciferase
activity was measured after serum stimulation. Empty vector and
the
wild-type TFII-I were also used in the same experiment as
negative and
positive controls. The results are shown in Fig.
6B. Interestingly, the
mutant L289A-TFII-I, which is defective
for ERK binding due to the
D-box mutation, was not able to potentiate
the c-
fos
promoter upon serum stimulation, whereas the wild-type
TFII-I enhanced
the promoter response as expected. Thus, these
results suggest that the
interaction between TFII-I and ERK is
required for the activity of
TFII-I on the c-
fos promoter.
Regulation of the interaction between TFII-I and ERK by signal
transduction pathways.
To further analyze the interaction between
TFII-I and ERK, we investigated whether TFII-I-ERK complex formation
can be observed between endogenous proteins in a signal-dependent
manner. NIH 3T3 fibroblasts were serum starved for 36 h and then
stimulated with 15% FCS for 10 min. Total cell extracts were
immunoprecipitated with anti-TFII-I antibody and blotted with anti-ERK
(or anti-phosphoERK) antibody to detect the interaction between
endogenous TFII-I and ERK. As shown in Fig.
7A, TFII-I did form a stable complex with ERK upon serum stimulation. In this assay, ERK activation by serum was
verified by anti-phosphoERK (pERK) antibody blotting (panel D), and the
activated ERK was indeed found in the complex (panel B). The
anti-TFII-I (panels C and F) and anti-ERK (panel E) Western blots show
that the expression level of TFII-I and ERK are comparable between
samples. These results demonstrate that endogenous TFII-I and ERK
interact with each other and that complex formation between TFII-I and
ERK can be regulated by serum stimulation.
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FIG. 7.
Serum stimulation enhances complex formation between
TFII-I and ERK. NIH 3T3 fibroblasts were serum starved for 36 h
(lane 1) and stimulated with 15% FCS for 10 min (lane 2). Total
extracts were immunoprecipitated with anti-TFII-I antibody. The
immunoprecipitates (A, B, and C) and total extracts (D, E, and F) were
fractionated by SDS-12% PAGE and blotted with anti-ERK (A and E),
anti-phosphoERK (B and D), or anti-TFII-I (C and F) antibody.
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It was shown in Fig.
1 and
2 that Ras and Rho pathways cooperate with
TFII-I for c-
fos promoter activation. To further investigate
the roles of the Ras or Rho pathway in TFII-I function, we examined
whether dominant-negative N17-Ras, N19-Rho, or N17-Rac can affect
the
interaction between TFII-I and ERK. To do this, GST-TFII-I
and HA-ERK
expression plasmids were cotransfected into COS-1 cells
with various
expression plasmids encoding dominant-negative N17-Ras,
N19-Rho, or
N17-Rac. Protein complexes were isolated by GST pulldown
and analyzed
by Western blot analyses. The interaction between
TFII-I and ERK was
detected by Western blotting with anti-HA antibody.
The results are
shown in Fig.
8. Coexpression of the
dominant-negative
N17-Ras greatly reduced the interaction between
TFII-I and ERK,
as can be seen in lane 2 of panel A. Panels B and C
show that
there was comparable expression of the transfected TFII-I and
ERK between the samples. This suggests that a functional Ras pathway
is
required for the interaction between TFII-I and ERK. This also
indicates that the Ras may regulate the activity of TFII-I by
the
modulation of MAP kinase interaction. Interestingly, dominant-negative
N19-Rho did not significantly affect the interaction between TFII-I
and
ERK (Fig.
8A, lane 3), although it did inhibit the activity
of TFII-I
on the c-
fos promoter (Fig.
2). This indicates that
the Rho
pathway regulates TFII-I through a mechanism other than
MAP kinase
interaction.
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FIG. 8.
N17-Ras abrogates the interaction between TFII-I and
ERK. pEBG-TFII-I and HA-ERK1 expression plasmids were cotransfected
into COS-1 cells in the presence of pCDNA3 (lane 1), N17-Ras (lane 2),
N19-RhoA (lane 3), or N17-Rac1 (lane 4). Transfected COS-1 cells were
lysed and subjected to GST pulldown assay. Glutathione-Sepharose
bead-bound proteins (A and C) and total extracts (B) were fractionated
by SDS-12% PAGE and analyzed by anti-HA (A and B) or anti-GST (C)
antibody Western blotting.
|
|
Previously it has been suggested that interaction of the Elk-1 D domain
with ERK is dependent on the activated form of ERK
(
53). To
determine whether the same may be true for TFII-I,
we examined whether
the Mek1 inhibitor PD98059 can interfere the
interaction between TFII-I
and ERK by inhibiting ERK activation.
Thus, GST-TFII-I and HA-ERK
expression plasmids were cotransfected
into COS-1 cells and treated
with PD98059 for 1 h before harvest.
SB202190, a specific
inhibitor for p38 kinase was also used as
a negative control. Protein
complexes were isolated and analyzed
as in Fig.
8, and the results are
shown in Fig.
9. Interestingly,
as can be
seen in lane 2 of panel A, MAP kinase inhibition did
not abolish the
ability of TFII-I to interact with ERK. The inhibitory
effect of
PD98059 in this experiment was verified by anti-phosphoERK
Western
blotting (Fig.
9B, lane 2). The inhibitors did not affect
the overall
expression of transfected ERK and TFII-I (Fig.
9C
and D). This suggests
that the interaction between TFII-I and
ERK is dependent on a
Ras-regulated pathway that is distinct from
the MAP kinase pathway.
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|
FIG. 9.
PD98059 does not disrupt the interaction between TFII-I
and ERK. pEBG-TFII-I and HA-ERK1 expression plasmids were
cotransfected into COS-1 cells, and the transfected COS-1 cells were
then incubated with 25 µM PD98059 (lane 2) or SB202190 (lane 3) for
1 h prior to harvest. The cells were lysed and subjected to GST
pulldown assay. GSH-Sepharose bead-bound proteins (A and D) and total
extracts (B and C) were fractionated by SDS-12% PAGE and analyzed by
anti-HA (A and C), anti-phosphoERK (B), or anti-GST (D) antibody
Western blotting.
|
|
The D box is required for ERK-dependent phosphorylation of
TFII-I.
We have found that functionally active ERK is required for
the activity of TFII-I (Fig. 4) and that the interaction between TFII-I
and ERK is not affected by MAP kinase inactivation (Fig. 9). In order
to understand how ERK is required for the activation of TFII-I, we
examined whether TFII-I may be a direct substrate of ERK. This is
suggested by the presence of two consensus MAP kinase substrate sites
as shown in Fig. 10A. Moreover, the
sequence of this region of TFII-I is very similar to the known MAP
kinase phosphorylation sites of Elk-1 (16, 29). To test
this, HA-tagged ERK was overexpressed in EGF-treated COS-1 cells and
immunoprecipitated by using anti-HA antibody, and an in vitro kinase
assay was carried out in the presence of [-32P]ATP.
GST-TFII-I protein was purified as described in Materials and Methods
and added to the reaction as a substrate. As can be seen in Fig. 10B,
TFII-I was efficiently phosphorylated in vitro by ERK (lane 2 of
subpanel A). To assess whether these putative MAP kinase substrate
sites of TFII-I are in fact phosphorylated by ERK, two serine point
mutations of TFII-I were generated by changing serine 627 or 633 of
TFII-I to alanines as previously described in Fig. 6. These mutants are
referred to here as S627A-TFII-I or S633A-TFII-I. To determine
whether these two serine mutants affected the ability of ERK to
phosphorylate TFII-I, purified S627A-TFII-I or S633A-TFII-I was also
analyzed by the same in vitro kinase assay. The mutant S633A-TFII-I
exhibited greatly reduced phosphorylation by ERK (lane 5 of subpanel
A), and S627A-TFII-I also showed a substantial decrease in its
phosphorylation (lane 4 of subpanel A). These results suggest that S627
and S633 are the major MAP kinase phosphorylation sites on TFII-I. It
was shown in Fig. 6 that the intact D box of TFII-I is required for its interaction with ERK and also for its activity in vivo. Thus, we
examined whether L289A-TFII-I, which is defective of ERK interaction due to its mutations in the D box, can be normally phosphorylated by
ERK. As can be seen in lane 3 of subpanel A, L289A-TFII-I was poorly
phosphorylated by ERK compared to the wild-type TFII-I. Phosphorylation
efficiency of different TFII-I mutants for ERK in comparison with the
wild type was presented also in subpanel B by quantitating the
32P incorporation of each band. There were equal amounts of
purified TFII-I protein used in each reaction as shown by anti-GST
antibody Western blotting in subpanel C. None of these point mutations disrupted the overall structure of TFII-I since none of these mutations
affected the ability of TFII-I to bind DNA (data not shown). These
results indicate that the TFII-I interaction with ERK is necessary for
its optimal phosphorylation by ERK as was also found for Elk-1
(53).
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|
FIG. 10.
TFII-I is an ERK substrate, and the consensus
phosphorylation sites are required for its activity. (A) Consensus MAP
kinase phosphorylation sites found in TFII-I and comparison to the
known Elk-1 phosphorylation sites (16, 29, 53). (B) TFII-I
phosphorylation by ERK. HA-ERK expression plasmid was transfected into
COS-1 cells. After transfection, cultures were maintained for 40 h
in 10% FCS containing DMEM before 10 min of EGF stimulation. Cell
extracts were then immunoprecipitated by using anti-HA antibody, and an
in vitro kinase assay was carried out in the presence of
[-32P]ATP. The wild-type-TFII-I (lane 2),
L289A-TFII-I (lane 3), S627A-TFII-I (lane 4), or S633A-TFII-I (lane
5) protein was purified as described in Materials and Methods and added
to the reaction as a substrate. No substrate except
[-32P]ATP was added to the reaction in lane 1. 32P incorporation into each band was quantitated with a
phosphorimager in the middle panel. The comparable amount of the
purified TFII-I protein used in each reaction was shown by anti-GST
antibody Western blotting in the bottom panel. (C) TFII-I requires ERK
phosphorylation sites for its enhancement activity on the
c-fos promoter. pEBG, pEBG-TFII-I (wild type),
pEBG-S627A-TFII-I, or S633A-TFII-I plasmid was transfected into NIH
3T3 fibroblasts with a c-fos-luciferase reporter construct.
Cells were serum starved for 36 h in 0.5% CS and then stimulated
for 4 h with 10% FCS. Cell extracts were then processed for
luciferase activity.
|
|
Next, we investigated whether ERK phosphorylation sites of TFII-I are
required for its activity. As previously described in
Fig.
6B,
S627A-TFII-I or S633A-TFII-I were transfected into NIH
3T3
fibroblasts to determine their in vivo functionality for the
c-
fos promoter. The results are shown in Fig.
10C. Both
S627A-TFII-I
and S633A-TFII-I, which showed reduced phosphorylation
by ERK
(Fig.
10B), failed to potentiate the c-
fos promoter
in response
to serum as the wild-type TFII-I had done. Therefore,
serines
627 and 633 of TFII-I are required for its in vivo activity on
the c-
fos promoter.
Both Ras and Rho pathways are required for the activity of
TFII-I.
Since Ras and Rho pathways regulate TFII-I through
distinct mechanisms, we attempted to demonstrate whether TFII-I
requires both pathways for its activity or whether either of these
pathways is sufficient to give rise to the activation of TFII-I for the c-fos promoter enhancement. To do this, we carried out
c-fos reporter assay after the transfection with different
combinations of activated or dominant-negative Ras and Rho expression
plasmids in the absence or presence of TFII-I, and luciferase activity
was measured without serum stimulation. Rac expression plasmids were
also used as controls. The results are shown in Fig.
11. In control samples, activated V12-Ras (lane 2) and L63-Rho (lane 4) efficiently synergized with TFII-I for c-fos promoter activation in the presence of
other normally functioning endogenous signal transduction pathways. However, interestingly, the activated L63-Rho was not able to cooperate
with TFII-I in the presence of dominant-negative N17-Ras (lane 7) and,
likewise, coexpression of the activated V12-Ras and TFII-I could not
further enhance the activity of the c-fos promoter in the
presence of dominant-negative N19-Rho (lane 12). The dominant-negative
N17-Rac did not block the cooperation between TFII-I and the activated
V12-Ras or L63-Rho (lane 9 and 10). These results indicate that both
the Ras and the Rho pathways need to be functioning for the effects of
TFII-I on the c-fos promoter and further indicate that the
Ras and Rho pathways function in distinct parallel pathways to regulate
TFII-I.
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|
FIG. 11.
Both Ras and Rho pathways are required for the activity
of TFII-I on the c-fos promoter. V12-Ras (lane 2, 9, and
12), L61-Rac (lane 3, 6, and 13), or L63-Rho (lane 4, 7, and 10)
expression plasmid were transfected into NIH 3T3 fibroblasts with the
c-fos-luciferase reporter construct in the absence or
presence of TFII-I. pCDNA3 (lanes 1 to 4), N17-Ras (lanes 5 to 7),
N17-Rac (lanes 8 to 10), or N19-Rho (lanes 11 to 13) plasmid was also
included in the transfection as indicated. After the transfection, the
cells were maintained for 40 h in 0.5% CS before harvest. Cell
extracts were then processed for luciferase activity.
|
|
| |
DISCUSSION |
Ras- and Rho-mediated signal transduction pathways play pivotal
roles in transducing signals for a variety of cellular responses. The
Ras pathway controls cell proliferation and differentiation in many
different cell types, and the Rho family small G proteins regulate
intracellular cytoskeletal structures as well as cell proliferation and
gene expression (14). It has been demonstrated that Ras
efficiently regulates the Raf/Mek1/ERK MAP kinase cascade among other
signal transduction pathways, whereas Rho signaling is less well
understood (17, 18, 28).
In this report, we have found that both Ras and RhoA modulate the
ability of TFII-I to stimulate the c-fos promoter. Both activated or dominant-negative Ras and RhoA coexpression have dramatic
effects on the ability of TFII-I to enhance c-fos promoter activity, whereas Rac and Cdc42 showed only partial effects. Other activators of ERK, Raf and Mek1, also effectively synergize with TFII-I
for the activation of the c-fos promoter, whereas a specific Mek1 inhibitor, PD98059, which leads to the inactivation of ERK, eliminated the activity of TFII-I on the c-fos promoter. We
thus conclude that TFII-I is functionally dependent on the Ras/ERK pathway.
Consistent with these findings, we have found that ERK binds directly
to TFII-I and that this interaction is modulated by both serum and Ras.
Importantly, this interaction can be detected not only with transfected
proteins but also with the endogenous proteins. We have found that ERK
interacts with TFII-I through the consensus ERK binding motif known as
the D box (52, 53). Abrogation of ERK binding to TFII-I by
mutation of the D box on TFII-I disrupts the ability of TFII-I to
enhance c-fos promoter activation. This result strongly
suggests that ERK binding is required for its activity. This is likely
due to the fact that TFII-I is a substrate for ERK. We have found that
TFII-I can be phosphorylated by ERK in vitro. Moreover, mutation of the
consensus MAP kinase phosphorylation sites on TFII-I reduces both its
ability to be phosphorylated by ERK in vitro and its ability to
activate the c-fos promoter. These data suggest that the
role of the D box in TFII-I is to target ERK to TFII-I as a substrate.
Consistent with this, we have found that mutation of the D box of
TFII-I also reduces its ability to be phosphorylated by ERK. This is similar to findings from other proteins such as Elk-1 that contain a D
box (52, 53).
Our findings that either mutation of the potential ERK phosphorylation
sites or inhibition of ERK activity with PD98059 inhibits the ability
of TFII-I to enhance c-fos promoter activation suggests that
phosphorylation of TFII-I modulates its transactivation function. Consistent with this, the S627A and S633A mutants retained the ability
to bind DNA despite losing activity (data not shown). S627 and S633 are
in a region of striking homology to the Elk-1 phosphorylation sites
which are known to regulate the transactivation function of Elk-1
(29). Thus, it seems likely that phosphorylation of these
serines in TFII-I regulates its transactivation function as well.
Substrate binding has been implicated as a mechanism for ensuring
kinase specificity (20, 51-53). However, there may be other roles for ERK targeting. It is possible that by binding to a
transcription factor like Elk or TFII-I, ERK is targeted to specific
promoters, where it then can phosphorylate other transcription factors
in the promoter enhancer complex. For instance, direct interaction between SRF and MAP kinases has not been demonstrated, and SRF does not
contain the conserved D box motif. However, SRF can be phosphorylated
on serine 103 by pp90rsk, which is a kinase
immediately downstream of ERK (38). Since SRF and TFII-I
interact each other at the protein level and bind to the
c-fos SRE (13, 24), TFII-I could target MAP
kinase to SRF. It is of note that the SRF-related proteins MEF2A and MEF2C which, unlike SRF itself, contain the D box, can bind to p38 MAP
kinase directly and serve as substrates as well (51). Although, in case of the c-fos promoter, the TCFs could
target MAP kinases to the promoter, there are other immediate-early
gene promoters which contain the SRE but do not bind TCFs
(49). TFII-I might play a more important role for targeting
MAP kinases to these promoters than the c-fos promoter.
We have found that ERK binding to TFII-I is regulated both by serum and
dominant-negative Ras. It remains an open question as to how ERK
binding to TFII-I is regulated. One possibility is that this is simply
a consequence of cellular relocalization of ERK such that when
activated ERK translocates to the nucleus it is now able to bind to
nuclear TFII-I. However, this is not a possibility we favor. We find
that a substantial fraction of TFII-I is cytoplasmic and in B cells the
localization of TFII-I is itself regulated (33). Thus, when
dominant-negative Ras inhibits TFII-I-ERK interaction, both proteins
are cytoplasmic yet unassociated. Interestingly, PD98059 eliminates the
activity of TFII-I on the c-fos promoter but did not affect
the ability of TFII-I to bind ERK. This indicates that TFII-I requires
functional ERK for its activity but not for its interaction with ERK
per se. This result also distinguishes TFII-I from Elk-1 in that Elk-1
only binds to the activated form of ERK (53). The failure of
PD98059 to inhibit TFII-I-ERK interaction further implies that Ras
regulates the ERK-TFII-I interaction via an ERK-independent signaling
pathway. Interestingly, in preliminary experiments, we have found that the dominant-negative Ras reduces TFII-I tyrosine phosphorylation (data
not shown). This raises the possibility that signal-dependent tyrosine
phosphorylation of TFII-I regulates its interaction with ERK.
It is significant that the activity of TFII-I can be modulated by RhoA.
There is strong evidence for a signal transduction pathway that leads
from RhoA to SRF (18). Though the detailed mechanism of the
RhoA/SRF pathway has yet to be fully elucidated, it seems possible that
TFII-I functions in this pathway. TFII-I binds to SRF (13,
24), and its activity is modulated by RhoA (this study). Even
though the RhoA/SRF pathway is independent of Elk-1, this pathway
remains dependent on Ras activation as we have found for TFII-I
(18). Interestingly, despite the fact that RhoA affects the
activity of TFII-I on the c-fos promoter, dominant-negative
RhoA fails to disrupt the interaction between TFII-I and ERK, whereas
dominant-negative Ras does. This indicates that Ras and RhoA regulate
TFII-I by distinct mechanisms. Because dominant-negative RhoA inhibits
the signaling of activated Ras to TFII-I and vice versa, the Rho and
Ras pathways appear to function in parallel rather than in a linear
pathway for TFII-I activation. Thus, TFII-I may also play a role in the
RhoA/SRF pathway, as well as in the Ras/ERK pathway. We are currently
investigating this possibility further.
| |
ACKNOWLEDGMENTS |
We are grateful to Larry Feig, Denise Toksoz, and Philip Tsichlis
for providing some of the expression plasmids used in these experiments. We also thank Larry Feig for anti-ERK antibody.
This work was supported by National Institutes of Health grant
R01-GM51551 to B.H.C.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Cellular and Molecular Physiology, Tufts University School of Medicine, 136 Harrison Ave., Boston, MA 02111. Phone: (617) 636-0442. Fax: (617)
636-6745. E-mail: cochran{at}opal.tufts.edu.
| |
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Molecular and Cellular Biology, February 2000, p. 1140-1148, Vol. 20, No. 4
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Abstract
Introduction
