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Previous Article | Next Article 
Molecular and Cellular Biology, November 1999, p. 7519-7528, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Requirement for Ras/Rac1-Mediated p38 and c-Jun N-Terminal Kinase
Signaling in Stat3 Transcriptional Activity Induced by the
Src Oncoprotein
James
Turkson,1,2
Tammy
Bowman,1,2
Jalila
Adnane,2,3
Yi
Zhang,1,2
Julie Y.
Djeu,2,4
Madhavi
Sekharam,1,5
David A.
Frank,6
Lawrence B.
Holzman,7
Jie
Wu,1,2,5
Said
Sebti,2,3 and
Richard
Jove1,2,*
Molecular Oncology,1
Drug Discovery,3 and
Immunology4 Programs, Moffitt Cancer
Center and Research Institute, Department of Biochemistry and
Molecular Biology,2 and Department of
Medical Microbiology and Immunology,5
University of South Florida College of Medicine, Tampa, Florida 33612;
Department of Adult Oncology, Dana-Farber Cancer Institute,
Boston, Massachusetts 021156; and
Department of Internal Medicine, University of Michigan Medical
School, Ann Arbor, Michigan 481097
Received 19 February 1999/Returned for modification 20 April
1999/Accepted 5 August 1999
 |
ABSTRACT |
Signal transducers and activators of transcription (STATs) are
transcription factors that mediate normal biologic responses to
cytokines and growth factors. However, abnormal activation of certain
STAT family members, including Stat3, is increasingly associated with
oncogenesis. In fibroblasts expressing the Src oncoprotein,
activation of Stat3 induces specific gene expression and is required
for cell transformation. Although the Src tyrosine kinase induces
constitutive Stat3 phosphorylation on tyrosine, activation of
Stat3-mediated gene regulation requires both tyrosine and serine
phosphorylation of Stat3. We investigated the signaling pathways
underlying the constitutive Stat3 activation in Src oncogenesis. Expression of Ras or Rac1 dominant negative protein blocks
Stat3-mediated gene regulation induced by Src in a manner consistent
with dependence on p38 and c-Jun N-terminal kinase (JNK). Both of these
serine/threonine kinases and Stat3 serine phosphorylation are
constitutively induced in Src-transformed fibroblasts. Furthermore,
inhibition of p38 and JNK activities suppresses constitutive
Stat3 serine phosphorylation and Stat3-mediated gene regulation. In
vitro kinase assays with purified full-length Stat3 as the substrate
show that both JNK and p38 can phosphorylate Stat3 on serine. Moreover,
inhibition of p38 activity and thus of Stat3 serine phosphorylation
results in suppression of transformation by v-Src but not v-Ras,
consistent with a requirement for Stat3 serine phosphorylation in Src
transformation. Our results demonstrate that Ras- and Rac1-mediated p38
and JNK signals are required for Stat3 transcriptional activity induced by the Src oncoprotein. These findings delineate a network of tyrosine
and serine/threonine kinase signaling pathways that converge on Stat3
in the context of oncogenesis.
| |
INTRODUCTION |
Signal transducers and activators of
transcription (STATs) were originally discovered as latent cytoplasmic
transcription factors that mediate cellular responses to diverse
cytokines and growth factors (for reviews, see references 17,
18, and 55). STATs are activated by
tyrosine phosphorylation, dimerize, and subsequently translocate to the
nucleus, where they regulate the transcription of genes by binding to
specific DNA response elements. Studies have implicated normal STAT
signaling in controlling fundamental biological processes,
including cell differentiation, proliferation, apoptosis,
and development (7, 15, 26, 33, 60, 78). Multiple signaling
pathways are simultaneously induced in response to cytokine or growth
factor stimulation, consistent with complex regulation by signal cross
talk. For example, maximum transcriptional activity of certain STATs
requires serine phosphorylation mediated by serine/threonine kinases of
other signaling pathways (3, 19, 51, 68). The kinases that
mediate STAT serine phosphorylation are not fully defined, although
evidence implicates multiple serine kinase signals, including
mitogen-activated protein kinases (MAPKs)/extracellular signal-regulated kinases (ERKs) (19), an H7-sensitive serine kinase (5), and a MAPK kinase (MKK)-dependent,
ERK-independent serine kinase (11).
MAPKs represent a family of serine/threonine protein kinases comprising
ERK1/ERK2 (ERKs), p38/HOG1 (p38), and c-Jun N-terminal kinase
(JNK)/stress-activated protein kinase (SAPK) (reviewed in references
24, 43, and 59). Ras and Ras-like
small G proteins are key regulators in the signaling pathways
leading to MAPK activation. For the Ras-ERK branch, sequential protein phosphorylations are mediated by the serine/threonine kinase
Raf-1 and the dual-specificity MKKs, which in turn phosphorylate and activate ERKs (24, 48, 49, 72). For the JNK and p38
pathways, the Rac1/Cdc42 subfamily of small G proteins is a key
mediator, together with Ras (for reviews, see references 24,
43, and 59). Several serine/threonine
protein kinases that are members of the mixed-lineage kinases (MLK),
such as dual leucine-zipper bearing kinase (DLK), have been identified
as upstream activators of MKKs (23, 24, 38). Activation of
JNK is largely induced by MKK4 and MKK7, while MKK3 and MKK6
preferentially activate p38 (22, 24, 62, 75). Activated
MAPKs ultimately phosphorylate transcription factors in the nucleus
that are responsible for the regulation of immediate-early genes, such
as c-fos, whose functional roles include control of cell
proliferation (35, 37, 71).
Emerging evidence strongly implicates abnormal activation of STAT
signaling in oncogenic transformation. Our laboratory and others have
previously reported constitutively active STATs, particularly Stat3 and
Stat5, in cells transformed by v-Src, v-Abl, and various other
oncoproteins and tumor viruses (4, 9, 13, 16, 29, 45, 46,
76; see reference 28 for a review).
Moreover, constitutive activation of Stat3 proteins occurs with high
frequency in human tumor cells (10, 12, 29, 31, 61, 66,
77; reviewed in reference 28), suggesting
a role for aberrant Stat3 signaling in malignant progression. Recent
studies have demonstrated an obligatory requirement for Stat3 signaling
in transformation by the Src oncoprotein (6, 63). The
mechanisms of subversion of the normal, highly regulated STAT signaling
by Src and other oncoproteins are still not fully defined.
Understanding how oncoproteins alter STAT signaling should provide
further insights into the role of abnormal STAT activation in
oncogenesis and may suggest a mechanistic basis for circumventing the
oncogenic process. The uniqueness of Stat3 as the sole STAT family
member constitutively active in Src-transformed fibroblasts makes this
system an excellent model for investigating the regulation of Stat3
signaling in oncogenesis.
Based on this model system, we investigated the signaling pathways
involved in aberrant activation of Stat3 in cells expressing the Src
oncoprotein. We demonstrate that induction of Stat3-mediated gene
regulation by v-Src is strictly Ras dependent in NIH 3T3 cells, since
Stat3 function is completely abrogated by the expression of dominant
negative Ras. This Ras dependency is reflected in the inhibition of
Stat3 transcriptional activity by dominant negative MKK1 or by the
MKK1/2 inhibitor PD98059. Similarly, transcriptional regulation by
Stat3 is inhibited by dominant negative forms of Rac1, DLK, and MKK4,
as well as by the p38 inhibitor SB202190. Constitutive activation of
p38 and JNK, together with constitutive Stat3 serine phosphorylation,
is observed in Src-transformed cells. Moreover, inhibition of both p38
and JNK is associated with suppression of Stat3 serine phosphorylation
and transcriptional activity. Both JNK and p38 phosphorylate Stat3 on
serine in vitro. Furthermore, inhibition of p38 activity blocks growth
in soft agar of v-Src-transformed cells, consistent with a requirement
for p38-mediated Stat3 serine phosphorylation in Src transformation.
Thus, we define a network of multiple tyrosine and serine kinase
pathways that converge on Stat3 signaling in fibroblasts expressing
oncogenic Src and are required for Stat3-mediated gene induction.
| |
MATERIALS AND METHODS |
Plasmids.
The Stat3 reporter pLucTKS3,
myc-p38mapk, myc-p46sapk,
dominant negative DLK (K185A), dominant negative MKK4 (dnMKK4),
N17-Ras, and NT-Raf have all been previously described (23, 52,
63). The pLucTKS3 reporter harbors seven copies of a sequence
corresponding to the Stat3-specific binding site in the C-reactive
protein gene promoter (63). The v-Src expression vector
pMvSrc has been described previously (40). Dominant negative
forms of ERK2, and MKK1 (34, 69) were generous gifts from M. Weber (University of Virginia) and N. Ahn (University of Colorado),
respectively. The Rac1-I115 (activated) and Rac1-17N (dominant
negative) vectors were generated by inserting Rac1 cDNA fragments from
pZipNeo (41) into pcDNA3 (Invitrogen) at a BamHI site.
Cell culture and transfections.
NIH 3T3, NIH 3T3/v-Src, and
NIH 3T3/v-Ras fibroblasts were grown in Dulbecco's modified Eagle's
medium (DMEM) containing 5% iron-supplemented bovine calf serum.
Transient transfections were carried out by the standard calcium
phosphate method as previously described (63). NIH 3T3
fibroblasts were seeded at 5 × 105 cells/100-mm plate
in DMEM plus 5% bovine calf serum at 18 to 24 h prior to
transfection. The total amount of DNA used for transfections was
typically 20 µg per plate, including 4 µg of luciferase reporter construct (pLucTKS3), 0.2 µg of 
-galactosidase (-Gal) internal control vector, and the amounts of expression vector indicated in the
figure legends. Transfection was terminated 15 h later by
aspirating the medium, washing the cells with phosphate-buffered saline
(PBS), and adding fresh DMEM. For generation of NIH 3T3/v-Src/TKS3 cell
lines stably expressing the Stat3 reporter, NIH 3T3/v-Src cells were
transfected with Fugene 6 (Boehringer Mannheim) as specified by the
supplier. The transfection mixture contained 5.5 µg of total DNA per
10-cm plate, including 5 µg of the Stat3 reporter pLucTKS3 and 0.5 µg of pcDNA3 that carries the neomycin resistance gene. Individual
G418-resistant clones were picked and characterized with regard to
Stat3-dependent luciferase activities.
Preparation of cytosolic and nuclear extracts.
In the case
of stable NIH 3T3/v-Src/TKS3 clones, cells were treated with inhibitors
or dimethyl sulfoxide for 6 h before preparation of cytosolic
extracts. For transient-expression assays, cytosolic extracts were
prepared from cells at 48 h posttransfection as previously
described (63). Briefly, after two washes with PBS and
equilibration for 5 min with 0.5 ml of PBS-0.5 mM EDTA, the cells were
scraped off of the dishes and the cell pellet was obtained by
centrifugation (4,500 × g for 2 min at 4°C). The
cells were resuspended in 0.4 ml of low-salt HEPES buffer (10 mM HEPES
[pH 7.8], 10 mM KCl, 0.1 mM EGTA, 0.1 mM EDTA, 1 mM
phenylmethylsulfonyl fluoride, 1 mM dithiothreitol) for 15 min, lysed
by the addition of 20 µl of 10% Nonidet P-40 (NP-40), and
centrifuged (10,000 × g for 30 s at 4°C) to
obtain the cytosolic supernatant, which was used for luciferase assays
(Promega) with a luminometer and for detection of -Gal activity by
colorimetric assay at an absorbance at 570 nm. As an internal control
for transient-transfection efficiency, the results were normalized to
-Gal activity. For electrophoretic mobility shift assay (EMSA),
nuclear extracts were prepared from transiently transfected NIH 3T3
cells and volumes containing equal amounts of total protein were
incubated with 32P-labeled M67SIE oligonucleotide probe
(64), as previously reported (29, 76). Supershift
assays were performed with rabbit polyclonal antibodies specific for
C-terminal amino acid residues of Stat3 (750 to 769) or Stat1 (688 to
710) proteins (Santa Cruz Biotechnology).
Soft-agar colony formation assay.
Colony formation assays
were carried out with six-well dishes. Each well contained 1.5 ml of
1% agarose in DMEM as the bottom layer. The top layer consisted of 1.5 ml of 0.5% agarose in DMEM containing 4,000 or 6,000 NIH 3T3/v-Src or
NIH 3T3/v-Ras fibroblasts, respectively. Treatment with inhibitors was
initiated 1 day after seeding cells by adding 75 to 100 µl of medium
with or without inhibitors and repeated once a week until large
colonies were evident. For quantitation, the colonies were stained by
adding 20 µl of 1-mg/ml iodonitrotetrazolium violet to each well and incubating at 37°C overnight; stained colonies were counted the next day.
Western blot analysis.
Whole-cell lysates were prepared in
boiling sodium dodecyl sulfate (SDS) sample-loading buffer to extract
total proteins from the cytoplasm and nucleus as well as preserve the
in vivo phosphorylation states. Equivalent amounts of total cellular
protein were electrophoresed on an SDS-10% polyacrylamide gel and
transferred to nitrocellulose membranes. Probing of nitrocellulose
membranes with primary antibodies and detection of horseradish
peroxidase-conjugated secondary antibodies by enhanced
chemiluminescence (Amersham) were performed as previously described
(29, 63, 76). The probes used were rabbit polyclonal antibodies against N-terminal amino acid residues (626 to 640) of Stat3
(Santa Cruz Biotechnology), phosphoserine-727 of Stat3 (25),
active (phosphorylated) JNK, p38mapk, or ERKs
(New England Biolabs), or total JNK, p38mapk or ERKs (Santa
Cruz Biotechnology).
Purification and phosphorylation of Stat3 and recombinant Stat3
proteins.
Stat3 and Stat3 were purified from
baculovirus-infected Sf-9 insect cells with biotinylated M67SIE
oligonucleotides. Briefly, Sf-9 cells were infected with baculoviruses
encoding Stat3 or Stat3. At 48 h postinfection, the cells were
lysed with NP-40 lysis buffer (50 mM HEPES [pH 7.9], 150 mM NaCl, 1%
NP-40, 20 mM NaF, 1 mM Na3VO4, 1 mM
Na4P2O4, 1 mM dithiothreitol, 0.5 mM phenylmethylsulfonyl fluoride, 2 mM EDTA, 0.1 µM aprotinin, 1 µM leupeptin, 1 µM antipain) and centrifuged (13,000 × g for 15 s at 4°C). The supernatant cell lysates were
supplemented with glycerol (to 10%) and 10 µg of
poly(dI-dC)-poly(dI-dC) in a final volume of 1 ml and incubated at
4°C for 30 min. Then 2 µg of 5'-biotinylated DNA fragment,
containing two copies of the M67SIE sequence
(5'-AGCTTCATTTCCCGTAAATCCCTA) (64), was added,
and the mixture was further incubated at 4°C for 2 h with slow
rotation. Subsequently, 100 µl of avidin-agarose beads (50% slurry)
was added to the mixture and incubated for 30 min. The beads were then
collected by centrifugation and washed four times with NP-40 lysis
buffer and three times with kinase buffer (25 mM HEPES [pH 7.5], 10 mM magnesium acetate). After a final centrifugation (3,000 × g for 2 min), the pellets of Stat3 and Stat3-bound
Sepharose beads were incubated for 5 min at room temperature in 35 µl
of kinase buffer containing approximately similar activities of
purified p38 (AG Scientific), JNK (BIOMOL), or ERK (BIOMOL) protein
kinases. Subsequently, 5 µl of [
-32P]ATP solution
(50 µM ATP; 0.5 µCi/µl) was added, and the mixture was
further incubated at 30°C. After 30 min, SDS-polyacrylamide gel
electrophoresis loading buffer was added and the samples were electrophoresed on an SDS-8% polyacrylamide gel and exposed for autoradiography.
| |
RESULTS |
Ras-mediated signaling is required for Stat3 transcriptional
activity.
We previously reported that Stat3 is constitutively
activated in NIH 3T3 fibroblasts stably transformed by v-Src
(76), and we demonstrated its transcriptional potential and
its requirement in Src transformation (63). In the present
study, we investigated the signaling pathways leading to the induction
of Stat3 transcriptional activity by using a Stat3-specific luciferase
reporter (pLucTKS3) harboring the Stat3-binding site from the
C-reactive protein gene promoter (63). The induction by
v-Src of Stat3-specific luciferase reporter was completely abrogated by
coexpression of the dominant negative Ras mutant (N17-Ras) or an
N-terminal fragment of Raf-1 (NT-Raf) designed to sequester Ras
(11, 52) (Fig. 1A). These findings suggest an obligatory requirement of Ras-mediated signaling for Stat3 transcriptional activity in NIH 3T3 fibroblasts expressing v-Src.
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FIG. 1.
Ras-MKK1/2-dependent signaling is required for
Stat3-mediated gene regulation induced by v-Src. NIH 3T3 cells were
transiently transfected with indicated plasmids. Luciferase activities
were measured in cytosolic extracts prepared 48 h posttransfection
and normalized to -Gal activity. (A) NIH 3T3 cells were transfected
with pLucTKS3 reporter alone or with reporter and v-Src expression
vector, pMvSrc, with or without vectors encoding N17-Ras or NT-Raf as
indicated. The N17-Ras and NT-Raf proteins inhibit Ras in a dominant
negative manner. (B) Cells were transfected with reporter alone or with
reporter and pMvSrc and treated with the MKK1/2 inhibitor PD98059 for
6 h or left untreated. (C) Cells were transfected with reporter
alone or with reporter and pMvSrc, with or without vectors encoding the
dominant negative ERK2 mutant, TAYF, or the MKK1 dominant negative
mutant, dnMKK1. Values shown in each panel are means and standard
deviations of at least four independent transfections, each performed
in triplicate.
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We then tested whether the MKK-ERK pathway downstream from Ras is
associated with induction of Stat3 transcriptional activity by Src.
Results of luciferase reporter assays with the pharmacologic MKK1/2-selective inhibitor PD98059 (21) or the dominant
negative MKK1 (dnMKK1) show that inhibition of MKK1/2 activity
significantly suppresses transcriptional regulation by Stat3 (Fig. 1B
and C). However, expression of a dominant negative form of ERK2, TAYF (19, 34), had no inhibitory effect on Stat3 transcriptional activity (Fig. 1C), suggesting that ERK2 activity is not required for
Stat3-mediated gene regulation induced by v-Src. We confirmed the ERK2
dominant negative activity of TAYF by inhibition of another luciferase
reporter, pLucSRE, which is not dependent on Stat3 (63) but,
rather, is dependent on the activation of the c-fos serum
response element by ERKs (36, 73). Because both dnMKK1 and
PD98059 block MKK signaling directly, these findings support a role for
MKK-mediated signaling in Stat3 transcriptional activity (11). We cannot definitively exclude a possible role for
ERKs, since ERKs associate with Stat3 in vivo and in vitro
(39) and phosphorylate Stat3 protein in vitro (see below)
(14). Together, our results indicate that a Ras-MKK-mediated
signaling pathway interacts with Stat3 signaling. The lack of a
complete block of Stat3 activity following inhibition of MKK1 or MKK2
(Fig. 1B and C) suggests that other signaling pathways contribute to
Stat3 transcriptional activity.
Stat3 transcriptional activity depends on Rac1-mediated
signaling.
Because the Rac1 subfamily of small G proteins plays a
key role in signaling downstream from Ras (24, 43, 59), we
investigated the contribution of Rac1-induced signals to Stat3
transcriptional activity. In luciferase reporter assays, the
coexpression of dominant negative Rac1 (N17 Rac1) or activated Rac1
(I115 Rac1) mutants significantly inhibited or enhances Stat3
transcriptional activity, respectively (Fig.
2A), suggesting that Rac1 lies in the
pathway leading from v-Src to Stat3 activation. To further explore the contribution of Rac1-mediated signals to Stat3 signaling, we examined the role of DLK, a member of the MLK family that participates in
activation of the stress pathway by v-Src (23, 47). Dominant negative DLK (K185A) significantly inhibited the induction of Stat3-specific luciferase reporter activity (Fig. 2B). DLK interacts with complexes containing other MLK members (70), and
dominant-negative DLK appears to interfere with the function of other
members of the MLK family (38a). Therefore, these findings
implicate the entire MLK family but do not define which member is
required in Stat3 signaling induced by v-Src. Interestingly, the
coexpression of JNK1 (myc-p46sapk) or p38
(myc-p38mapk) proteins reversed this inhibitory
effect in a concentration-dependent manner (Fig. 2B and C). We infer
that the kinase activities of the overexpressed JNK1 or p38 proteins
can sustain a level of serine phosphorylation sufficient for
maximal Stat3 transcriptional activity even at marginal MLK
activity. Together, these findings indicate that Rac1-mediated
p38 and JNK activities contribute to Stat3 signaling induced by v-Src.
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FIG. 2.
Stat3-mediated gene regulation induced by v-Src requires
Rac1- and MLK-dependent p38 and JNK signals. NIH 3T3 cells were
transiently transfected with the indicated plasmids, and luciferase
activities were assayed as described for Fig. 1. (A) Cells were
transfected with the Stat3 reporter pLucTKS3 alone, reporter plus
v-Src, or reporter plus v-Src plus dominant negative Rac1 (N17 Rac1),
or activated Rac1 (I115 Rac1). (B) Cells were transfected with reporter
alone, reporter plus v-Src, or reporter plus v-Src plus dominant
negative DLK (K185A) or p46sapk or both. (C)
Cells were transfected with reporter alone, reporter plus v-Src, or
reporter plus v-Src plus K185A or p38mapk or
both. (D) Cells were transfected with reporter alone or reporter plus
v-Src and treated or not treated with the
p38mapk inhibitor SB202190 or the PI 3-kinase
inhibitor wortmannin. Values are means and standard deviations of at
least three independent experiments.
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That p38 is central to Stat3 signaling is further corroborated by
studies showing significant inhibition of Stat3-specific luciferase
reporter induction in cells transiently expressing the Stat3-specific
reporter and treated with SB202190, a pharmacologic inhibitor selective
for p38 (65) (Fig. 2D). Because phosphatidylinositol 3-kinase (PI 3-kinase) involved in Ras-mediated signaling has previously been shown to be activated in Src-transformed cells (27), we investigated any contribution it might make to
Stat3 signaling by using wortmannin, a PI 3-kinase inhibitor
(74). The results showed no inhibition of Stat3-specific
luciferase reporter induction in fibroblasts transiently expressing
v-Src and treated with this inhibitor (Fig. 2D), thus excluding a role for PI 3-kinase in transcriptional regulation by Stat3. Our results support the model that induction of Stat3 transcriptional activity by
v-Src requires Rac1-mediated p38 and JNK signals.
Evidence of distinct JNK and p38 pathways involved in Stat3
transcriptional activity.
Reports in the literature delineate two
distinct pathways leading to the activation of JNK and p38 (see
reference 24 for a review). While both pathways
utilize a common signal from Rac1, they emerge as separate signals at
the level of MKKs. For example, MKK4 and MKK7 largely activate JNK,
while MKK3 and MKK6 preferentially activate p38. To test whether
this divergence in signaling is relevant to Stat3 function, we first
examined the effect of dnMKK4 on transcriptional activation by
Stat3. Expression of dnMKK4 significantly blocked Stat3-specific
luciferase reporter induction (Fig.
3A), suggesting a requirement for MKK4 in
the signaling leading to Stat3 transcriptional activity. The divergence
in JNK and p38 signals was evident when only the coexpression of
JNK1 (myc-p46sapk), but not p38
(myc-p38mapk), abrogated the inhibitory
effect of dnMKK4 and restored Stat3 transcriptional activity
(Fig. 3). These results establish that transcriptional activation by
Stat3 utilizes the MKK4-JNK pathway and confirm that distinct
MKKs mediate the pathways leading to p38 and JNK activation. We infer
from these results that Stat3-mediated gene regulation induced by v-Src
requires Ras-Rac1-mediated activation of the stress pathway in a manner
analogous to normal extracellular stimulus-induced activation of this
pathway.
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FIG. 3.
v-Src-induced Stat3-mediated gene regulation requires
MKK4-dependent JNK signaling. NIH 3T3 cells were transiently
transfected with the indicated plasmid vectors, and luciferase
activities were assayed as described for Fig. 1. (A) Cells were
transfected with pLucTKS3 reporter alone, reporter plus v-Src, or
reporter plus v-Src plus dnMKK4 or myc-p46sapk
or both. (B) Cells were transfected with reporter alone, reporter plus
v-Src, or reporter plus v-Src plus dnMKK4 or
myc-p38mapk or both. Values are means and
standard deviations of at least three independent transfections.
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JNK and p38 kinases mediate the key role of Ras in Stat3
transcriptional activity.
Because inhibition of Ras function (Fig.
1A) is expected to block the activities of downstream MAPKs, we tested
whether the abrogation of Stat3 transcriptional activity following
dominant negative inhibition of Ras is due to lack of sufficient
functional MAPKs. If this is the case, overexpression of the MAPKs
would be expected to restore kinase activities and hence Stat3
function. In confirmation of this prediction, coexpression of all three MAPK family proteins brought about recovery of Stat3 transcriptional activity that would otherwise have been blocked by dominant negative inhibition of Ras (Fig. 4).
Interestingly, differences emerged in the pattern and extent of
restoration of Stat3 transcriptional activity. Similar to p38 or JNK1,
the expression of low levels of ERK2 resulted in partial recovery of
Stat3 transcriptional activity (Fig. 4). However, as the level of ERK2
expression increases, Stat3 transcriptional activity declines.
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FIG. 4.
Stat3-mediated gene regulation induced by v-Src requires
Ras-dependent p38mapk and JNK activities. NIH
3T3 cells were transiently transfected with pLucTKS3 reporter alone,
reporter plus v-Src, or reporter plus v-Src plus N17-Ras with or
without vectors encoding ERK2, myc-p38mapk or
myc-p46sapk. Luciferase activities were assayed
as described for Fig. 1. Values are means and standard deviations of
three independent experiments.
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While there is not yet an explanation for this phenomenon, it is
consistent with previous reports that ERK kinase activity can
down-regulate Stat3 function via a number of mechanisms. These include
inhibition of upstream kinases, such as JAK family members (56), dephosphorylation of phosphotyrosine in Stat3
(14), and formation of an ERK-Stat3 complex (39).
While we do not exclude any of these events in our system, it is also
relevant that constitutive activation of ERKs is not detected in many
fibroblast cell lines stably transformed by v-Src (32, 58)
(see Fig. 6). As compelling evidence that p38 and, to a lesser extent,
JNK mediate the role of Ras in Stat3 transcriptional activity,
coexpression of either of these MAPKs caused a complete or partial
rescue of Stat3 function from inhibition by dominant negative Ras (Fig. 4). The extent of this restoration was dependent on the level of p38 or
JNK expression. We deduce that the overexpressed p38 or JNK proteins
compensate for the loss of kinase activities. Together, our findings
provide strong evidence of cooperation of Ras-mediated p38 and JNK
pathways with v-Src for the induction of Stat3 transcriptional activity.
Serine phosphorylation and DNA-binding activity of Stat3 in
fibroblasts expressing v-Src.
In the context of transformation by
v-Src, our results suggest a cross-communication of signals involving
the p38 and JNK serine/threonine kinases and Stat3. The prediction is
that in addition to tyrosine phosphorylation, Stat3 undergoes
constitutive serine phosphorylation in Src-transformed cells for
induction of transcriptionally functional Stat3. To test this
assumption, we first assayed for Stat3 serine phosphorylation levels by
Western blot analysis with phosphoserine-727-specific anti-Stat3
antibodies (25, 30). Strikingly, our results showed that
Stat3 was constitutively phosphorylated on serine 727 in
Src-transformed fibroblasts compared to their normal counterparts (Fig.
5A, lanes 1 and 2). To determine if MAPK
members are required for this event, we treated Src-transformed fibroblasts with PD98059 or SB202190 and prepared cell lysates for
phosphoserine-Stat3 Western blot analysis. Treatment with either
PD98059 or SB202190 blocked serine phosphorylation of Stat3 (lanes 2 to
4). These results establish that Stat3 serine phosphorylation is
constitutive in NIH 3T3 fibroblasts stably transformed by Src and
provide evidence that MAPK family members are major mediators of this
effect.
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FIG. 5.
Analyses of constitutive Stat3 serine phosphorylation
and SIE-binding activity induced by v-Src. (A) Western blot analysis of
whole-cell lysates prepared from normal NIH 3T3 fibroblasts and
Src-transformed counterparts treated with PD98059 or SB202190 for
6 h or left untreated (lanes 2 to 4). Samples were probed with
antibodies specific to phosphoserine-727 (bottom) or the N-terminal
portion (top) of Stat3. (B) Nuclear extracts were prepared from NIH 3T3
cells transfected with v-Src. Equal amounts of total protein were
incubated with 32P-labeled M67SIE and subjected to EMSA.
Cells were transfected with empty vector alone (NIH 3T3) or v-Src
vector and treated with PD98059 or SB202190 for 6 h or left
untreated (lanes 2 to 5). Competitions of radiolabeled M67SIE-binding
activity present in nuclear extracts of NIH 3T3 cells transfected with
v-Src alone (lanes 6 and 7) were performed with a 100-fold molar excess
of unlabeled M67SIE or the unrelated FIRE oligonucleotides. Supershifts
(lanes 8 and 9) were performed with antibodies specifically recognizing
either Stat1 or Stat3 ( -Stat1, -Stat3). The asterisk indicates
positions of supershifted complexes.
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We next explored whether PD98059 and SB202190 have an influence on the
Stat3 DNA-binding activity induced by v-Src. Nuclear extracts were
prepared from fibroblasts expressing v-Src that have been treated with
inhibitors or left untreated. STAT DNA-binding activities in extracts
containing equal amounts of total proteins were analyzed by EMSA with
an oligonucleotide probe corresponding to the M67 variant of the
c-fos gene sis-inducible element (SIE), which binds both
activated Stat1 and Stat3 (64). As previously reported
(29, 63, 76), expression of v-Src induced Stat3 tyrosine
phosphorylation and DNA-binding activity (Fig. 5B, lanes 1 and 2).
Moreover, treatment of v-Src-expressing cells with PD98059 or SB202190
had no effect on Stat3 DNA-binding activity induced by v-Src (lanes 2 to 4). For controls, the binding of Stat3 to M67SIE was competitively
inhibited by a molar excess of cold, unlabelled M67SIE but not by the
unrelated c-fos intragenic regulatory element (FIRE)
oligonucleotide, showing the specificity of DNA binding. Furthermore,
Stat3 binding was blocked and supershifted by anti-Stat3 antibodies but
not by anti-Stat1 antibodies, demonstrating that the DNA-binding
complex in this case contained Stat3. We conclude from these results
that inhibition of Stat3 serine phosphorylation has no effect on the
constitutive Stat3 DNA-binding activity in cells expressing v-Src,
consistent with earlier findings that Stat3 DNA-binding activity is
independent of serine phosphorylation (67). Taken together,
our findings demonstrate that constitutive Stat3 serine phosphorylation
in Src-transformed cells is dependent on signaling through MAPK family members.
p38 and JNK are activated in Src-transformed fibroblasts.
Because the results presented above suggest that p38 and JNK are key
components of the signaling leading to Stat3 transcriptional activity
induced by v-Src, we determined whether these kinases are
constitutively activated in cell lines stably transformed by Src. The
activity levels of p38, JNK, and ERKs were assayed by Western blot
analysis with antibodies specific to the phosphorylated, activated
forms. Significantly, we observed that both p38 and JNK1/2 were highly
activated in v-Src-transformed compared to normal NIH 3T3 fibroblasts
(Fig. 6A and B, lanes 2 and 3). In contrast, no substantial induction of ERK1/2 was observed in
Src-transformed over normal NIH 3T3 cells, consistent with previous
reports (32, 58) (Fig. 6C, lanes 2 and 3).
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FIG. 6.
p38 and JNK are constitutively induced in
Src-transformed cells and phosphorylate Stat3 in vitro. (A) Western
blot analysis of whole-cell lysates prepared from normal NIH 3T3
fibroblasts (lane 2) or Src-transformed counterparts treated with or
without PD98059 or SB202190 (lanes 3 to 5). Samples were probed with
antibody specific to phospho-p38 (top) or total p38 (bottom). (B) The
whole-cell extracts described in panel A were analyzed by Western
blotting. Samples were probed with antibody specific to phospho-JNK1/2
(top) or total JNK1/2 (bottom). (C) The whole-cell extracts described
in panel A were analyzed by Western blotting. Samples were probed with
antibody specific to phospho-ERK1/2 (top) or total ERK1/2 (bottom). (D)
In vitro serine phosphorylation of Stat3 by JNK, p38, and ERKs.
Purified baculovirus-expressed Stat3 (lanes 1 to 4) and Stat3 (lanes
5 to 8) were incubated with [-32P]ATP together with or
without purified JNK, p38, or ERKs for 30 min and subjected to
SDS-polyacrylamide gel electrophoresis and autoradiography. For
positive identification, cell lysates from anisomycin-treated C6 glioma
cells with highly induced ERKs, p38, and JNK, served as standards (lane
1).
|
|
We next investigated the effects of PD98059 and SB202190 on the
activation of these MAPKs. As expected, treatment of Src-transformed fibroblasts with PD98059 caused a complete block of basal ERKs activity
(Fig. 6C, lanes 3 and 4). Surprisingly, however, treatment with the
same MKK1/2 inhibitor caused complete or partial suppression of JNK1/2
and p38 induction, respectively (Fig. 6A and B, lanes 3 and 4). These
results suggest either that the MKK1/2 inhibitor has a nonspecific
effect on other MKKs upstream of JNK and p38 or that MKK1/2 are
involved in JNK and p38 activation, as previously reported
(50). Combined with the results in Fig. 1B, these findings indicate that the suppression of Stat3 transcriptional activity by
PD98059 is the sum of the effects of this inhibitor on MKK1/2, JNK, and
p38 activities. While the block by PD98059 of basal ERK1/2 and induced
JNK1/2 activities is complete, there is only a partial inhibition of
Stat3-mediated gene regulation (compare Fig. 1B with Fig. 6B and C,
lanes 3 and 4). We speculate that the limited effect of PD98059 on
Stat3 function is at least in part due to its incomplete
inhibition of p38 activity, thus pointing to this MAPK member as the
major serine/threonine kinase required for Stat3 signaling.
Because SB202190 directly blocks p38 kinase activity, treatment
of Src-transformed cells with this inhibitor did not significantly
alter the phosphorylation of MAPK members, including p38 (Fig. 6A to C,
lanes 3 and 5). The apparent high induction of p38 phosphorylation when
SB202190 was present may be due to a positive feedback response by MKK3
or MKK6 to the diminished p38 kinase activity. Although the
activation of overexpressed exogenous JNK by v-Src has been previously
reported (23, 47), this is the first evidence of
constitutive activation of both endogenous p38 and JNK in stable
Src-transformed fibroblasts and supports the model that the activated
stress pathway cooperates with Stat3 signaling induced by Src.
Altogether, our findings provide evidence of cross talk between
Ras-Rac1-mediated activities of p38/JNK and Stat3 signaling in
Src-transformed cells.
Because our results implicate p38 and, to a lesser extent, JNK1/2 as
the key serine/threonine kinases involved in Stat3 signaling in
Src-transformed cells, we tested whether Stat3 can be a direct substrate for these MAPKs in vitro. The results shown in Fig. 6D
indicate that p38 and JNK can effectively phosphorylate Stat3 in vitro,
partly consistent with a previous report (14). The notable
difference between our study and this previous report was our use of
full-length Stat3 as the substrate and purified proteins of the MAPK
family. Stat3 phosphorylation by ERK, however, was minimal compared to
the levels achieved for JNK and p38. For a control, we used a splice
variant of full-length Stat3 with a C-terminal deletion, Stat3,
which lacks serine 727 and therefore cannot transactivate in many cell
types (8, 63). The Stat3 and Stat3 proteins used as
substrates in this assay maintained correct protein folding as they
were purified by virtue of their DNA-binding activity to a
Stat3-specific site. The results showed that Stat3 did not undergo
serine phosphorylation by any of the MAPKs (Fig. 6D), consistent with
serine 727 being the site of phosphorylation (14, 67). These
results suggest that all three MAPKs are capable of using Stat3 as
substrate in vivo, although the actual contributions of the individual
MAPK family members in vivo would be expected to depend on the extent
of their activation by v-Src.
Inhibition of p38 activity blocks constitutive Stat3 signaling and
Src transformation.
The above results of transient-transfection
assays with reporter constructs suggest that MKK-mediated p38 and, to a
lesser extent, JNK activities are required for constitutive Stat3
signaling in Src-transformed cells. To confirm this conclusion, we
tested the effects of inhibition of MKKs or p38 on the induction of the Stat3-dependent luciferase reporter, pLucTKS3, in v-Src-transformed fibroblasts that stably express this reporter. Because Stat3 is constitutively activated in Src-transformed cells (76), NIH 3T3/v-Src/TKS3 cells stably expressing the Stat3 reporter exhibit very
high luciferase activity, reflecting constitutive Stat3-dependent induction of this reporter. As seen in transient transfections, treatment of NIH 3T3/v-Src/TKS3 cells with PD98059 or SB202190 partially or completely suppressed constitutive induction of the Stat3-dependent luciferase reporter, respectively (Fig.
7A), consistent with an obligatory
requirement for p38 in constitutive Stat3 signaling in Src-transformed
cells. The present studies, combined with previous reports (6,
63), raise the possibility that p38-mediated Stat3 serine
phosphorylation is required for v-Src transformation. We tested this
hypothesis by investigating the effects of inhibition of p38 on
anchorage-independent growth of Src-transformed fibroblasts in
soft-agar suspension. Treatment of cells in agar with SB202190 completely blocked colony formation of Src-transformed cells (Fig. 7B).
In contrast, treatment with the same inhibitor had no significant effects on colony formation by Ras-transformed fibroblasts, which do
not require Stat3 activation (Fig. 7C) (6, 29, 63). Thus,
the inhibition by SB202190 of Src transformation is not the outcome of
gross cytotoxicity. These studies suggest that p38 activity and Stat3
serine phosphorylation are required for transformation by Src but not
by Ras. We also tested the effect of inhibition of MKK1/2 by PD98059 on
anchorage-independent growth of fibroblasts transformed by v-Src or
v-Ras. The results showed a lack of significant effect of this
inhibitor on transformation by either oncoprotein (Fig. 7B and C),
suggesting that inhibition of MKK1/2 is not sufficient to block Src or
Ras transformation. Together, these results demonstrate that p38
activity is required for Stat3-mediated gene regulation and v-Src
transformation.
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FIG. 7.
Inhibition of p38 activity blocks cell transformation by
v-Src and not by v-Ras. (A) NIH 3T3/v-Src/TKS3 cells stably transfected
with the Stat3-dependent luciferase reporter, pLucTKS3, were treated
with the indicated inhibitors for 6 h prior to cytosolic extract
preparation and luciferase assays as described for Fig. 1. Values are
the means and standard deviations of six independent assays. (B) NIH
3T3/v-Src fibroblasts seeded in soft-agar suspension were treated once
weekly with the indicated inhibitors until large-colony formation was
evident. Values are the means and standard deviations of 12 independent
assays. (C) NIH 3T3/v-Ras fibroblasts seeded in soft-agar suspension
were treated once weekly with the indicated inhibitors, and colonies
were counted as in panel B. Values are the means and standard
deviations of nine independent assays. DMSO, dimethyl sulfoxide.
|
|
| |
DISCUSSION |
Recent studies have established that constitutive activation of
Stat3 signaling participates in cell transformation by the oncogenic
Src tyrosine kinase (6, 63). Here we demonstrate that, in
parallel to the constitutive DNA-binding activity and tyrosine
phosphorylation of Stat3, the Src oncoprotein recruits additional
signaling pathways crucial for Stat3 function (Fig. 8). Upstream of these signals is Ras,
which functions to coordinately integrate serine/threonine kinase
activities necessary for efficient Stat3 transcriptional activity. As
one of the Ras-mediated pathways, MKK-ERK signaling interacts with that
of Stat3 (14, 19, 39, 51, 56). The interaction between ERKs
and Stat3 signaling, however, is complicated by results which indicate
that ERKs can down-regulate (14, 39, 56) as well as enhance
(19, 51) Stat3 tyrosine phosphorylation and transcriptional
activity. This disparity may be explained by our finding that low
levels of ERK2 induce while higher levels inhibit Stat3-mediated gene
regulation (Fig. 4). At the same time, the evidence indicates a role
for MKK1/2-mediated, ERK-independent signals in Stat3 transcriptional activity (11), consistent with transformation of NIH 3T3
fibroblasts by activated MKK1 mutants independently of ERKs
(2) and raising the possibility that MKK1/2 recruits p38 and
JNK serine/threonine kinases (50) for Stat3 signaling
induced by v-Src.
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FIG. 8.
Model of Stat3 phosphorylation by tyrosine and
serine/threonine kinase signaling pathways in Src oncogenesis. APRE,
acute-phase response element.
|
|
Positioned downstream from Ras, the Rac1 family of small G proteins is
key to signals that induce p38 and JNK serine/threonine kinases
(37, 71). We confirm that Rac1 signaling is recruited by
v-Src (23, 47) and extend these studies to demonstrate that
Stat3 signaling induced by v-Src requires components of Rac1 signaling,
including MLK family members and MKK4. The rescue of Stat3 function by
p38 and JNK proteins from inhibition induced by dominant negative Ras
provides compelling evidence that these serine/threonine kinases are
key in Src-induced Stat3 signaling. Thus, the essential role of Ras in
this Stat3 signaling is the recruitment of Rac1-mediated p38 and JNK
activities. It is also highly significant that both p38 and JNK
activities are constitutively induced in cells stably transformed by
Src. The aberrant constitutive activation of these two kinases may be
essential to maintain the observed elevated Stat3 serine
phosphorylation and transcriptional activity in Src-transformed cells.
This is the first demonstration of constitutive induction of p38, JNK,
and Stat3 serine phosphorylation in cells stably transformed by Src and
provides evidence that these events are associated. Whether these
events are unique to Src transformation or are common to cells
transformed by other oncogenic tyrosine kinases remains to be
determined. Our results are consistent with the finding that
transformation by the nonreceptor tyrosine kinase, v-Fps/Fes, requires
Ras- and Rac1-mediated activation of MAPK family members
(42). These findings set precedents for investigating
possible augmentation by Ras, Rac1, p38, and JNK pathways of aberrant
STAT signaling in human malignancies that harbor constitutively
activated STAT proteins (reviewed in reference 28).
We do not exclude the possibility that other serine/threonine kinases
contribute to Stat3 transcriptional activity in Src-transformed fibroblasts. Notably, studies show that v-Src activates various isoforms of protein kinase C (53), suggesting that the
latter may play a role in Src transformation. Others have also noted a
role for H7-sensitive serine kinases in Stat3 transcriptional activity
(5). On the other hand, our observations suggest that the PI
3-kinase pathway is unlikely to contribute to Stat3 signaling, although
it has previously been shown to be activated in Src-transformed cells
(27). Furthermore, we do not anticipate any role for the serine/threonine kinase AKT2, which is a downstream target of PI
3-kinase that is also activated by v-Src (20, 44). That PI
3-kinase and AKT2 may not be required for Stat3 signaling is supported
by the report that dominant negative inhibition of PI 3-kinase inhibits
transformation by V12 Ras but not by v-Src (54).
Our findings presented here define signal transduction networks from
v-Src to Stat3 in NIH 3T3 fibroblasts that integrate tyrosine and
serine/threonine kinase pathways (Fig. 8). This model predicts a key
role for Ras, which regulates the contributions of the MKK1/2 cascade
and the Rac1-mediated stress-activated pathways involving p38 and JNK.
While Ras plays an essential role in transformation of NIH 3T3 cells by
v-Src (57), more recent studies have demonstrated that Ras
is not required for Src transformation of chicken embryo fibroblasts or
Rat-2 fibroblasts (1). Thus, the requirement for
Ras-mediated signaling in Src transformation is cell type specific,
raising the possibility that Ras-independent pathways activate p38 and
JNK signaling leading to Stat3 transcriptional activity in different
cell types. On the other hand, NIH 3T3 cells harboring activated Ras do
not exhibit activated Stat3 (29), suggesting that Ras
signaling is necessary but not sufficient for transformation of these
cells by Src. Our results also indicate that downstream events, such as
p38 and JNK signaling, are not sufficient to induce Stat3
transcriptional activity in the absence of Src. Nevertheless,
activation of the stress signaling pathways involving p38 and JNK is
obligatory for Stat3 function.
Because serine phosphorylation of Stat3 is required for its maximal
transcriptional activity (68) and because Stat3 signaling is
obligatory for Src transformation (6, 63), we infer from the
present study that p38- and JNK-mediated Stat3 serine phosphorylation is necessary for Src oncogenesis. Consistent with this conclusion, earlier studies have demonstrated that a Stat3 mutant with a
Ser-727-to-Ala mutation blocks Src-mediated transformation in a
dominant negative manner (6). Thus, it is highly significant
that inhibition of p38-mediated Stat3 serine phosphorylation blocks
transformation by v-Src and not other oncoproteins like Ras, which do
not induce Stat3 signaling. These findings underscore the functional
importance of p38 in mediating Stat3 serine phosphorylation in Src
oncogenesis. In addition, the pathways delineated here are relevant to
normal Stat3 signaling because recent studies demonstrated that p38
induces Stat3 serine phosphorylation in T cells in response to
interleukin-12 and interleukin-2 (30). Our findings provide
the first evidence detailing cross talk between the Ras/Rac1-mediated
p38/JNK pathways and Stat3 signaling leading to serine phosphorylation
of Stat3 in the context of oncogenesis. While there are likely to be
other pathways essential for Stat3 function and Src transformation, our
study demonstrates a convergence at the level of Stat3 of multiple
signaling pathways activated by Src. These novel observations provide
new insight into some of the signaling pathways induced by the Src
oncoprotein that potentially play critical roles in cell transformation
and human cancer.
| |
ACKNOWLEDGMENTS |
We thank M. Weber and N. Ahn for generously providing dominant
negative ERK2 (TAYF) and MKK1, respectively, and members of the
laboratory for stimulating discussions.
This work was supported by the Molecular Biology and Molecular Imaging
Core Facilities of the Moffitt Cancer Center and Research Institute and
by NCI grants CA55652 (to R.J.) and CA76661 (to S.S.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Molecular
Oncology Program, Moffitt Cancer Center, 12902 Magnolia Dr., Tampa, FL
33612. Phone: (813) 979-6725. Fax: (813) 632-1436. E-mail:
richjove{at}moffitt.usf.edu.
| |
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Top
Abstract
Introduction
