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Molecular and Cellular Biology, November 1999, p. 7420-7427, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Cell-Extracellular Matrix Interactions Stimulate
the AP-1 Transcription Factor in an Integrin-Linked Kinase- and
Glycogen Synthase Kinase 3-Dependent Manner
Armelle A.
Troussard,1
Clara
Tan,1,2
T. Nathan
Yoganathan,3 and
Shoukat
Dedhar1,2,*
BC Cancer Agency and Vancouver Hospital, Jack
Bell Research Centre, Vancouver, British Columbia V6H
3Z6,1 Department of Biochemistry and
Molecular Biology, University of British Columbia, Vancouver,
British Columbia V6T 1Z3,2 and Kinetek
Pharmaceuticals, Inc., Vancouver, British Columbia V6P
6P2,3 Canada
Received 24 May 1999/Returned for modification 15 July
1999/Accepted 9 August 1999
 |
ABSTRACT |
Integrin-mediated interactions of cells with components of the
extracellular matrix regulate cell survival, cell proliferation, cell
differentiation, and cell migration. Some of these physiological responses are regulated via activation of transcription factors such as
activator protein 1 (AP-1). Integrin-linked kinase (ILK) is an ankyrin
repeat containing serine-threonine protein kinase whose activity is
rapidly and transiently stimulated by cell-fibronectin interactions as
well as by insulin stimulation. ILK activates protein kinase B and
inhibits the glycogen synthase kinase 3 (GSK-3) activity in a
phosphatidylinositol-3-kinase (PI 3-kinase)-dependent manner. We now
show that cell adhesion to fibronectin results in a rapid and transient
stimulation of AP-1 activity. At the same time, the kinase activity of
ILK is stimulated whereas that of GSK-3 is inhibited. This
fibronectin-dependent activation of AP-1 activity is inhibited in a
dose-dependent manner if the cells are transfected with wild-type
GSK-3, and also by inhibitors of PI 3-kinase. Stable or transient
overexpression of ILK results in a stimulation of AP-1 activity which
is inhibited by cotransfection with wild-type GSK-3 and
kinase-deficient ILK. Transient transfection of ILK in HEK-293 cells
stimulates complex formation between an AP-1 consensus oligonucleotide
and nuclear proteins containing c-jun. The formation of this complex is
inhibited by cotransfection with active GSK-3 or kinase-deficient ILK,
suggesting that ILK may regulate AP-1 activation by inhibiting GSK-3,
which has previously been shown to be a negative regulator of AP-1. In
the presence of serum, ILK has no effect on the phosphorylation of
Ser-73 in the N-terminal transactivation domain of c-jun. These results demonstrate a novel signaling pathway for the adhesion-mediated stimulation of AP-1 transcriptional activity involving ILK and GSK-3
and the subsequent regulation of the c-jun-DNA interaction.
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INTRODUCTION |
Integrin-mediated interactions of
cells with components of the extracellular matrix regulate cell
survival, cell proliferation, cell differentiation, and cell migration
(9, 11, 20, 44) by regulating the activity of transcription
factors such as activator protein 1 (AP-1) (4). The
activation of the c-jun N-terminal kinase (JNK) group of
mitogen-activated protein kinases (MAPK) has been proposed for the
regulation of AP-1 activity by cell-extracellular matrix interactions
(20).
The AP-1 family of transcription factors consists predominantly of
homodimeric or heterodimeric complexes of c-jun and c-fos proteins.
These complexes bind to a specific target DNA sequence, the
palindromic tetradecanoyl phorbol acetate (TPA)-responsive element
TGAC/GTCA (2, 3), which is found in the promoters of
many genes, including those for cell cycle regulators such as cyclin D1
(24), or vascular endothelial growth factor (25). The nuclear proto-oncogene product c-jun is a central component of all
AP-1 complexes and is expressed in many cell types at low levels
(29). c-jun contains a C-terminal DNA-binding/leucine zipper
domain and an N-terminal transactivation domain (28, 29).
AP-1 activity is tightly regulated at both the transcriptional and
posttranscriptional levels. In the latter case, dephosphorylation of
serine and threonine in the C-terminal domain of c-jun is necessary for
binding to DNA, while phosphorylation of serine-63 and serine-73 by
JNKs in the N-terminal domain promotes AP-1 transactivation (7, 8,
46). Although the activation of the N-terminal transactivation
domain of c-jun is well characterized in the activation of AP-1, the
contribution of the C-terminal DNA-binding domain to the regulation of
AP-1 is less well understood. It has been demonstrated that glycogen
synthase kinase 3 (GSK-3) can phosphorylate c-jun at C-terminal sites,
resulting in the inhibition of the DNA-binding activity of c-jun
(8, 21, 35, 39).
We have identified integrin-linked kinase (ILK), an ankyrin repeat
containing serine-threonine protein kinase, which interacts with the
cytoplasmic domains of integrin subunits (23).
Overexpression of ILK in epithelial cells results in
anchorage-independent cell survival and cell cycle progression via
upregulation of the expression of cyclin D1 (40). When
overexpressed in epithelial cells, ILK also induces nuclear
translocation of 
-catenin, resulting in the formation of an active
lymphoid enhancer factor 1 (LEF-1) transcription factor--catenin
complex and in the enhancement of LEF-1 transcriptional activity
(37). It has recently been shown that ILK activates protein
kinase B (PKB/AKT) and inhibits GSK-3 activity in a
phosphatidylinositol-3-kinase (PI 3-kinase)-dependent manner
(13, 15).
Here we show that AP-1 activity is induced by the interaction of cells
with fibronectin (FN) and that this activation is dependent upon the
activation of ILK, which, by inhibiting the activity of GSK-3, can
stimulate the binding of c-jun to the AP-1-responsive element.
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MATERIALS AND METHODS |
Cell lines.
Rat intestinal epithelial cells (IEC-18) were
cultured in 
-minimal essential medium (Gibco BRL, Burlington,
Ontario, Canada) supplemented with 5% fetal bovine serum (Gibco BRL),
2 mM L-glutamine (Gibco BRL) and 3.6 mg of glucose and 10 µg of insulin (Sigma, Oakville, Ontario, Canada) per ml. Stably
transfected IEC-18 cells with wild-type ILK in the sense orientation
(ILK-13 cells; clones A1a3 and A4a)
or the antisense orientation (ILK-14 cells; clones A2C3 and A2C6) were
established as described previously (23). Both ILK-13 and
ILK-14 cells were grown under conditions that were the same as those
for the parental IEC-18 cell line, except for the addition of 80 µg
of geneticin (G418; Gibco BRL) per ml to maintain selection. Human
embryonic kidney cells (HEK-293 cells; obtained from M. Moran,
University of Toronto) (22) were grown in Dulbecco's
modified Eagle medium (DMEM; Gibco BRL) supplemented with 10% donor
calf serum (Gibco BRL).
Adhesion assays.
Cells were serum starved for 18 h,
harvested by being scraped in phosphate-buffered saline (PBS)
containing 5 mM EDTA, and then seeded on plates coated with FN (10 µg
per ml of PBS; Gibco BRL) or bovine serum albumin (BSA; 2.5 mg per ml
of DMEM) and maintained with DMEM for an adequate length of time. For
AP-1 activity experiments after adhesion, cells were transfected by calcium phosphate as described by us (23) with 50 µg of
pGL3-AP-1 plasmid containing the AP-1-responsive promoter and the
luciferase reporter gene and other cDNAs. Adhesion assays were
performed 48 h after transfection, and the AP-1 activity was
measured by luciferase assay described below.
Kinase assays.
Kinase assays were carried out as described
by us (15). Cells were lysed in a solution containing 50 mM
HEPES (pH 7.5), 150 mM NaCl, 1% Nonidet P-40, 0.5% sodium
deoxycholate, 10 µg of leupeptin per ml, 2.5 µg of aprotinin per
ml, 1 mM phenylmethylsulfonyl fluoride (PMSF), 5 mM sodium fluoride,
and 5 mM sodium orthovanadate. Equivalent protein concentrations of
cell lysates were precleared with nonspecific immunoglobulin G (IgG)
and bound to protein A-Sepharose. The supernatants were
immunoprecipitated with the appropriate antibodies, and the kinase
assays were performed as described previously (23). Myelin
basic protein (MBP) was used as a substrate for ILK, and glycogen
synthase 1 peptide (GS-1) was used for GSK-3. Phosphorylated MBP was
detected after electrophoresis on sodium dodecyl sulfate-15%
polyacrylamide gel, and phosphorylated GS-1 was detected after
electrophoresis on a Tricine gel (43). The gels were
visualized by autoradiography. The autoradiographic signals were
quantified by densitometric analysis (Bio-Rad Laboratories, Canada).
Immunoblots.
Protein extracts were resolved by SDS-PAGE and
electrotransferred onto Immobilon-P membranes (Millipore, Nepean,
Ontario, Canada). Membranes were probed with the appropriate primary
antibody. The following antibodies were used: rabbit anti-ILK antibody
(0.5 µg/ml) (23), mouse anti-GSK-3 antibody (1:400;
Transduction Laboratories), mouse anti-V5 antibody (1:5,000;
Invitrogen, Carlsbad, Calif.), mouse anti-hemagglutinin (HA), antibody
(1 µg/ml; Babco, Richmond, Calif.), rabbit anti-c-jun antibody (1 µg/ml; Santa Cruz Biotechnology), rabbit anti-phospho-c-jun (Ser-73)
antibody (1 µg/ml; Upstate Biotechnology, Lake Placid, N.Y.), rabbit
anti-c-fos antibody (1 µg/ml; Santa Cruz Biotechnology), mouse
anti-phospho-extracellular signal-regulated kinase (Tyr-204) antibody
(1 µg/ml; Santa Cruz Biotechnology). Protein detection was carried
out with the appropriate horseradish peroxidase-conjugated secondary
antibody (Jackson Laboratory, Bar Harbor, Maine) and an enhanced
chemiluminescence detection system (Amersham Corp.).
Transient transfections.
Transient transfections were
performed with Lipofectin reagent (Gibco BRL) when serum-exposed cells
reached 40 to 50% confluency. Cells were transfected with AP-1,
-galactosidase, wild-type ILK-V5-tagged, ILK-kinase dead (ILK-KD),
wild-type GSK-3-HA-tagged, or AKT-kinase dead (AKT-KD) HA-tagged cDNAs.
The plasmids used were pGL3-AP-1 containing the AP-1-responsive
promoter and the luciferase reporter gene (from Kinetek
Pharmaceuticals, Inc.), pcDNA3.1-lacZ-V5 (Invitrogen), pcDNA3.1-ILK-V5,
pcDNA3-ILK-KD, pcDNA3-GSK-3-HA, pcDNA-AKT-KD-HA (mutant K179A), and the
corresponding empty vectors. Transfections were carried out overnight
in serum-free medium. The transfection medium was then replaced by
serum-containing medium, and cells were harvested 36 to 48 h later.
Luciferase assays for AP-1 activity.
Luciferase assays were
performed according to the manufacturer's instructions (Promega Corp.,
Madison, Wis.). All assays (except for those shown in Fig. 2F) were
normalized by measuring -galactosidase enzymatic activity
(42), and the luciferase reaction was then performed by
using lysates with an equivalent amount of -galactosidase activity.
For Fig. 2F, a dual-luciferase reporter assay (Promega) was performed.
Two reporters were cotransfected: the experimental AP-1 reporter and a
control reporter (Renilla). Both luciferase activities were
evaluated, and AP-1 activity was normalized to the activity of the
control. Protein concentrations were determined by a Bradford assay.
Results are expressed in relative light units per microgram of protein.
When testing inhibitors of AP-1 activity, cells were exposed to
wortmannin, LY294002, or PD98059 (Calbiochem, La Jolla, Calif.) prior
to harvesting the cells.
Nuclear extracts and gel shift assays.
Nuclear extracts were
prepared by the miniextraction method as previously described
(1). Cells were washed with ice-cold PBS and harvested by
being scraped in 1.5 ml of PBS. Cells were pelleted and resuspended in
400 µl of 10 mM HEPES-potassium hydroxide (pH 7.9)-1.5 mM magnesium
chloride-10 mM potassium chloride-0.5 mM dithiothreitol-0.2 mM PMSF.
After 10 min of incubation on ice, nuclei were pelleted by being spun
for 10 s and resuspended in 50 µl of 20 mM HEPES-potassium
hydroxide (pH 7.9)-25% glycerol-420 mM sodium chloride-1.5 mM
magnesium chloride-0.2 mM EDTA-0.5 mM dithiothreitol-0.2 mM PMSF.
Tubes were incubated for 20 min on ice and then centrifuged to clear
the cellular debris. Nuclear extracts were stored at 
70°C. Gel
shift assays were performed by incubating 2 µg of the nuclear
extracts for 20 min at room temperature with a
32P-end-labeled DNA fragment containing the putative
protein binding site (for AP-1, 5'CGC TTG ATG AGT CAG CCG GAA3';
Promega; [
-32P]ATP was from Amersham Life Science).
Reaction products were analyzed on a nondenaturing 5% polyacrylamide
gel (0.5% Tris-borate-EDTA, 3.5% glycerol). The specificity of the
DNA-protein interaction was established by competition experiments
using 10× cold AP-1 oligonucleotide as the competitor. For the
supershift assay, 10 µg of rabbit anti-c-jun antibody (Santa Cruz
Biotechnology) or nonspecific IgG was added to the reaction mixture,
subsequent to the addition of the 32P-labeled
oligonucleotide probe, and the mixture was incubated for 45 min at room
temperature. Complexes were resolved by electrophoresis as described
for the gel shift assay.
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RESULTS |
Regulation of ILK, GSK-3, and AP-1 by adhesion to FN.
It has
recently been demonstrated that the attachment of rat intestinal
epithelial IEC-18 cells to FN stimulates ILK activity (15).
Since ILK directly phosphorylates GSK-3 in vitro and inhibits GSK-3
activity when overexpressed in cells (15), we examined whether adhesion to FN results in an inhibition of GSK-3 activity. Attachment of IEC-18 cells to FN led to increased ILK kinase activity, concomitant with decreased GSK-3 kinase activity, compared to attachment to BSA as a control (Fig. 1A).
Maximal stimulation of ILK activity occurred at 30 min after plating,
and this corresponds to the maximal inhibition of GSK-3 activity. As
shown previously (15), ILK activity declines after 30 min
and is substantially lower at 45 min after plating. At this time point,
the GSK-3 activity rebounds but is still lower than that for cells
plated on BSA. The autoradiographic signals were quantified by
densitometric analysis, and the data are shown in Fig. 1B. The
expression levels of ILK and GSK-3 did not change during the course of
cell adhesion to FN or BSA (Fig. 1A).
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FIG. 1.
Regulation of ILK, GSK-3, and AP-1 activities by
adhesion to FN. (A) ILK and GSK-3 kinase activities were measured
following an adhesion assay. IEC-18 cells were serum starved for
18 h, harvested, and seeded on FN or BSA for 30 or 45 min. ILK and
GSK-3 activities were determined with MBP and glycogen synthase 1 peptide as the substrates, respectively. Immunoblots with anti-ILK and
anti-GSK-3 antibodies show equivalent amounts of ILK and GSK-3 in each
extract. (B) Quantification of ILK and GSK-3 kinase activities by
densitometric analysis. ODu, optical density units. (C) Time course of
adhesion-induced stimulation of AP-1 activity. HEK-293 cells were
transfected by calcium phosphate with 50 µg of pGL3-AP-1 containing
the AP-1-responsive promoter and luciferase reporter gene. Cells were
then seeded on BSA or FN for the indicated times and lysed, and a
luciferase assay was performed. Results represent the difference
between adhesion to FN and to BSA. RLu, relative light units. (D)
Effect of GSK-3 on FN-induced AP-1 activity. HEK-293 cells were
cotransfected with 50 µg of pGL3-AP-1 and the indicated amounts of
pcDNA-GSK-3-HA-tagged and empty vector. Cells were harvested, seeded on
FN or BSA for 30 min, lysed, and assessed for AP-1 activity by
luciferase assay. GSK-3 expression in HEK-293 cells is shown by Western
blot analysis using an anti-HA antibody.
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We next wanted to determine whether cell attachment to FN resulted in
the stimulation of AP-1 activity and whether ILK and
GSK-3 were
upstream of this activation. To demonstrate this, we
switched to
HEK-293 (human embryonic kidney) cells, because these
cells have a
higher efficiency of transient transfection than
IEC-18 cells. We
measured AP-1 activity by a luciferase assay
of transiently transfected
HEK-293 cells with a plasmid containing
the AP-1-responsive promoter
and the luciferase reporter gene
at various time points of attachment
to FN or BSA. AP-1 activity
was maximally stimulated 30 min after
attachment to FN (Fig.
1C).
Cotransfection of the AP-1 reporter gene
with increasing amounts
of wild-type HA-tagged GSK-3 cDNA in HEK-293
cells resulted in
an inhibition of AP-1 activity induced by adhesion to
FN for 30
min (Fig.
1D).
These results demonstrate that attachment of cells to FN increases
ILK kinase activity, resulting in the inhibition of GSK-3
activity. Furthermore, adhesion-dependent stimulation of AP-1
activity is dependent on the inhibition of GSK-3
activity.
ILK regulates AP-1 in a GSK-3-dependent manner.
To further
understand the link between ILK and AP-1, we measured AP-1 activity in
intestinal epithelial cells (IEC-18) and in IEC-18 cells stably
transfected with ILK in the sense orientation (ILK-13; clones
A1a3 and A4a) and in the antisense
orientation (ILK-14) as controls (23). ILK-13 clones have
been shown to overexpress ILK (23) and to have higher
constitutive ILK activity (15). AP-1 activity was
severalfold higher in ILK-13 (A1a3) adherent
and nonadherent (data not shown) cells than in IEC-18 and ILK-14 cells
(Fig. 2A). All
independently derived ILK-overexpressing IEC-18 clones have previously
been shown to behave identically (23, 37, 40), and, indeed,
identical results were obtained for both independently derived ILK-13
clones, A1a3 and A4a. The data
shown in Fig. 2A are from the clone A1a3. Thus
overexpression of ILK in epithelial cells appears to mimic the effects
of adhesion on AP-1 activity, which is adhesion independent in these
cells. In addition, we also examined the protein expression levels of c-jun and c-fos in these three cell lines by Western blotting (Fig.
2A). As both c-jun and c-fos expression levels are equivalent, we
concluded that the increased AP-1 activity is not due to an elevated
expression of c-jun and c-fos in cells stably transfected with ILK.
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FIG. 2.
ILK regulates AP-1 activity in a GSK-3-dependent manner.
(A) AP-1 activity in IEC-18 cells and in IEC-18 cells stably
transfected with wild-type ILK (ILK-13; clone
A1a3 (37, 40) and anti-sense ILK
(ILK-14; clone A2C3) was measured. After
transfection of 0.5 µg of pGL3-AP-1 by Lipofectin, AP-1 activity was
determined by luciferase assay. c-jun and c-fos protein expression
levels in each cell line were estimated by Western blotting. RLu,
relative light units. (B) Overexpression of GSK-3 decreases AP-1
activity in ILK-13 cells. Luciferase assays were performed with ILK-13
cells transfected with 0.5 µg of pGL3-AP-1 and 0.5 µg of
pcDNA-GSK-3-HA or 0.5 µg of pcDNA-ILK-KD. Transfection and expression
of GSK-3 were established by Western blot analysis using an anti-HA
antibody. (C) AP-1 activity in HEK-293 cells transiently transfected
with ILK. HEK-293 cells were transiently cotransfected with 0.5 µg of
pGL3-AP-1 and 0.5 µg of pcDNA3.1-ILK-V5 or empty vector. ILK
expression in the transfected cells was detected by immunoblotting with
an anti-V5 antibody. (D) Dose-dependent effect of GSK-3 on ILK-induced
AP-1 activity. Increasing amounts of pcDNA-GSK-3-HA (0.125, 0.25, and
0.5 µg) were cotransfected with 0.5 µg of pGL3-AP-1 and 0.5 µg of
pcDNA3.1-ILK-V5, and AP-1 activity was evaluated. Expression of ILK and
GSK-3 in the transfected cells is shown by Western blotting with
anti-V5 and anti-HA antibodies, respectively. (E) Effect of ILK-KD on
ILK-induced AP-1 activity. The same experiment as that shown in panel D
was performed with 0.5 µg and 1 µg of pcDNA-ILK-KD. Expression of
ILK in the transfected cells was established by Western blot analysis
with an anti-V5 antibody. (F) Effect of AKT-KD on ILK-induced AP-1
activity. HEK-293 cells were cotransfected with 0.5 µg pGL3-AP-1, 0.5 µg of pcDNA3.1-ILK-V5, and 0.5 µg of pcDNA-GSK-3-HA or 0.5 µg of
pcDNA-AKT-KD-HA. Expression of ILK in the transfected cells was
established by Western blot analysis with an anti-V5 antibody.
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We next explored the role of GSK-3 in the regulation of AP-1 activity.
To investigate if ILK regulates AP-1 activity through
GSK-3, we
measured AP-1 activity in ILK-13 cells after transfection
of these
cells with wild-type GSK-3 or ILK-KD cDNAs. In the cells
stably
transfected with ILK, ILK-induced AP-1 activity is inhibited
both by
GSK-3 and by ILK-KD (Fig.
2B). Transfection with the empty
vector, as a
control, did not alter AP-1 activity (data not
shown).
To further understand the effects of GSK-3 and ILK-KD on AP-1 activity,
we carried out transient transfections in HEK-293
cells. Transient
transfection of ILK cDNA resulted in an approximately
twofold
stimulation of AP-1 activity compared to transfection
with the empty
vector (Fig.
2C). Cotransfection of ILK cDNA with
increasing amounts of
wild-type GSK-3 or ILK-KD cDNAs resulted
in a dose-dependent inhibition
of ILK-stimulated AP-1 activity
(Fig.
2D and E, respectively).
Overexpressed inactive ILK-KD protein
appears to function as a
dominant-negative molecule in this context.
These data show that ILK
regulates AP-1 activity via GSK-3.
We have recently shown that ILK activates PKB/AKT in a PI
3-kinase-dependent manner by phosphorylating the Ser-473 residue
(
15). It has also been reported that PKB/AKT inactivates
GSK-3
(
47). To determine whether PKB/AKT is involved in the
ILK-mediated
regulation of AP-1 activity, we evaluated AP-1 activity in
transiently
transfected HEK-293 cells with active ILK and two
dominant-negative
forms of PKB/AKT. Both mutants (K179A-PKB and
AAA-PKB) have previously
been shown to behave as dominant negative
molecules and to inhibit
endogenous PKB/AKT activity (
10,
18,
49). As shown in Fig.
2F, the dominant-negative mutant K179A-PKB
had no effect on ILK-induced
AP-1 activity, whereas wild-type GSK-3
clearly inhibited this
activity. Identical results were obtained with
the AAA-PKB dominant-negative
mutant (data not shown). These data argue
against the role of
PKB/AKT in the ILK- and GSK-3-dependent stimulation
of AP-1 activity
and suggest that ILK may be regulating GSK-3 activity
by direct
phosphorylation. We have previously shown that ILK can
directly
phosphorylate GSK-3 in vitro (
15).
FN- and ILK-mediated stimulation of AP-1 is dependent on PI
3-kinase.
We have also recently shown that ILK inhibits GSK-3
activity in a PI 3-kinase-dependent manner (15). Several
studies have implicated PI 3-kinase in AP-1 transactivation.
Specifically, TPA (27), epidermal growth factor, and insulin
(26) have all been shown to activate AP-1 in a PI
3-kinase-dependent manner. We therefore studied the effect of PI
3-kinase-specific inhibitors wortmannin and LY294002 (5, 48)
on FN adhesion-dependent and ILK-induced AP-1 activity via GSK-3. We
also used mitogen-activated protein kinase kinase (MEK) inhibitor
PD98059 (19) to study a potential role of the MAPK pathway
in this activation. FN adhesion-stimulated AP-1 activity was inhibited
by LY294002 (Fig. 3A), whereas both wortmannin and LY294002 inhibited
the stimulation of AP-1 activity by ILK in transfected HEK-293 cells
(Fig. 3B). The MEK inhibitor PD98059 had
a minimal effect on the ILK-induced AP-1 activity (Fig. 3B). These data
suggest that PI 3-kinase, ILK, and GSK-3 are involved in FN-mediated
cell adhesion stimulation of AP-1.
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FIG. 3.
FN- and ILK-mediated stimulation of AP-1 is dependent on
PI 3-kinase. (A) FN-induced AP-1 activity is sensitive to LY294002.
HEK-293 cells transfected by calcium phosphate with 50 µg of
pGL3-AP-1 were plated on BSA or FN for 30 min in the presence of the
indicated concentrations of LY294002, and AP-1 activity was evaluated
by luciferase assay. (B) ILK-induced AP-1 activity is sensitive to PI
3-kinase inhibitors. AP-1 activity in HEK-293 cells cotransfected by
Lipofectin with 0.5 µg of pGL3-AP-1 and 0.5 µg of pcDNA3.1-ILK-V5
was measured. PD98059 (25 µM), wortmannin (100 nM), LY294002 (10 µM), or dimethyl sulfoxide (DMSO) was added to the cell culture
medium 30 min prior to harvesting the cells. AP-1 activity was then
evaluated by a luciferase assay. ILK expression is shown by Western
blotting with anti-V5 antibody.
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ILK promotes complex formation between c-jun and an AP-1 consensus
oligonucleotide.
The AP-1 complex consists of dimeric
transcription factors composed of c-jun-c-jun or c-jun-c-fos, which
bind to the palindromic TPA-responsive element sequence TGA(C/G)TCA and
enhance gene expression (2, 3). It is known that one of the
components of AP-1, c-jun, is phosphorylated by GSK-3 in a region
proximal to the DNA-binding domain (amino acids 247 to 263), resulting
in decreased DNA binding (35). We therefore analyzed the
ability of c-jun to form a complex with an AP-1 consensus
oligonucleotide (14) in the presence of ILK and GSK-3.
HEK-293 cells were transfected with AP-1 reporter gene and ILK cDNAs,
without or with GSK-3 or ILK-KD cDNAs. Cell lysates for luciferase
assays and nuclear extracts for gel mobility shift assays were
prepared. As expected, the expression of ILK in HEK-293 cells increased
AP-1 activity and the cotransfection of GSK-3 or ILK-KD decreased this
activity (data not shown). Gel mobility shift analysis (Fig.
4A) showed that a protein-DNA complex was
induced in HEK-293 cells transfected with ILK cDNA (lane 2 [lanes are
numbered from left to right]) compared with HEK-293 cells transfected
with the empty vector (lane 1). Cotransfection of GSK-3 cDNA inhibited
this ILK-induced complex formation (lane 3), and cotransfection of
ILK-KD cDNA reduced the amount of the complex (lane 4). To determine
whether the ILK-induced complex contains c-jun, we carried out a
supershift assay using an anti-c-jun antibody to highlight the presence
of c-jun in the complexes (Fig. 4B). As can be seen, anti-c-jun
antibody induced a protein-DNA mobility shift in the complex,
indicating the massive presence of c-jun. The results show that ILK
activates the binding of c-jun to its DNA response element and that
this stimulation requires the inhibition of GSK-3, since the presence of wild-type GSK-3 suppresses the ILK-induced activation. The MEK
inhibitor PD98059 did not have a significant effect on the ILK-induced
complex formation (Fig. 4A, lane 5). As shown by Western blot analyses
in Fig. 4, the effects of ILK on c-jun-DNA complex formation and AP-1
activation appear to be independent of the N-terminal phosphorylation
of c-jun, because ILK had no effect on the further stimulation, over
and above that of serum, of Ser-73 phosphorylation by JNK. This
phosphorylation was also not modified by the coexpression of GSK-3 or
ILK-KD. Furthermore, although ILK stimulates the phosphorylation of
ERK-1 (Fig. 4A) but does not affect ERK-1 expression (not shown),
inhibition of this phosphorylation by PD98059 did not significantly
affect the c-jun-DNA complex formation, demonstrating that the ILK-
and GSK-3-dependent activation of AP-1 is mediated by the regulation of
the DNA-binding domain of c-jun.
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FIG. 4.
ILK-induced AP-1 activity is mediated by c-jun. (A) In
this band shift assay, serum-exposed HEK-293 cells were transfected by
Lipofectin with 0.5 µg of each of the indicated cDNAs. PD98059 (25 µM) was added to the medium 12 h prior to harvesting the cells.
Nuclear extracts (2 µg) from the transfected cells were incubated
with 32P-end-labeled AP-1 consensus oligonucleotide
containing the protein binding site. Reaction products were analyzed on
a nondenaturing 5% polyacrylamide gel (left gel). The specificity of
complex formation was established by a competition experiment using
cold AP-1 oligonucleotide as the competitor (right gel). For immunoblot
studies, 10 µg of protein was resolved by SDS-10% PAGE. c-jun
(Ser-73) phosphorylation, c-jun protein expression level, ERK
phosphorylation (Tyr-204), and ERK protein expression level (not shown)
were determined by Western blot analysis. ILK and GSK-3 expression
levels in the transfected cells were evaluated by Western blot analysis
using anti-V5 and anti-HA antibodies, respectively. (B) Anti-c-jun
antibody shifts ILK-induced AP-1 complex. Nuclear extracts (2 µg)
from HEK-293 cells transfected with ILK-V5 cDNA were incubated with
32P-AP-1 oligonucleotide in the absence or presence of
anti-c-jun antibody or nonspecific IgG (10 µg). The latter did not
induce a mobility shift of the complex (not shown).
|
|
| |
DISCUSSION |
The data presented in this paper demonstrate a novel signaling
pathway for the activation of the AP-1 transcription factor via cell
adhesion to FN. In this pathway, ILK regulates AP-1 activity through
GSK-3. We have shown that adhesion of cells to FN stimulates ILK
activity. Since the regulation of ILK activity is PI 3-kinase dependent
(15), we have shown, with the use of pharmacologic PI
3-kinase inhibitors wortmannin and LY294002, that adhesion and
ILK-mediated AP-1 activation are PI 3-kinase dependent. ILK, by
inhibiting GSK-3, may prevent the GSK-3 dependent C-terminal phosphorylation of one or more sites located near the DNA-binding domain of c-jun. This would then result in the promotion of the formation of a DNA-protein complex containing c-jun, enhancing AP-1
activity (Fig. 5). Our data demonstrate
further that although ILK regulates the activities of both
PKB/AKT and GSK-3 in a PI 3-kinase-dependent manner (15), it
is the PKB-independent regulation of GSK-3 by ILK that is involved in
AP-1 stimulation.
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|
FIG. 5.
Schematic model for ILK-induced AP-1 activity. ILK
regulates AP-1 activity through the GSK-3 pathway. Stimulation of ILK
activity by adhesion of cells to FN results in an inhibition of GSK-3
activity, likely via direct phosphorylation of GSK-3. Inhibition of
GSK-3 could prevent phosphorylation of the C terminus DNA-binding
domain of c-jun, resulting in the formation of a protein-DNA complex
and consequently an enhancement of AP-1 activity.
|
|
Integrin-mediated cell adhesion is known to regulate gene expression
via transcription factors such as NF-
B and AP-1 (6). A
number of signal transduction pathways, normally associated with the
binding of soluble growth factors to their receptors, are also
activated by integrin engagement (44). There is evidence that the growth factor-mediated activation of PI 3-kinase and downstream elements, such as PKB/AKT, depends on cell adhesion (31). Cell anchorage via integrins can activate the PI
3-kinase PKB/AKT pathway, leading to the suppression of cell
detachment-induced apoptosis or anoikis (30). Integrin
engagement also triggers activation of the Raf-1/MEK/MAPK pathway
(33, 41). However, in this case, integrin-mediated adhesion
itself does not result in mitogenesis; soluble growth factors are also
required. Three groups of MAPK have been identified: ERK, p38 MAPK, and
JNK (12). JNK can be activated upon integrin clustering
(33) and by a variety of environmental signals (16, 32,
45). Targets of the JNK signal transduction pathway include the
transcription factor c-jun (50). The fact that JNK enhances
AP-1 activity by binding to the N-terminal region of c-jun and
phosphorylating serine-63 and -73 within the activation domain has been
well characterized (29, 50).
Several lines of evidence indicate that the C-terminal DNA-binding
domain of c-jun also regulates AP-1 activity. It has been shown that in
resting cells, in which AP-1 activity is low, c-jun is phosphorylated
on three amino acid residues located near the DNA-binding domain
(8). Activation of these cells by TPA leads to an increase
in the DNA binding of AP-1. This is independent of any protein
synthesis and results in the specific dephosphorylation of c-jun in the
C-terminal domain. These authors showed that, in vitro, GSK-3 can
efficiently phosphorylate c-jun on these sites, resulting in
decreased DNA-protein interaction. Later, these in vitro results were
confirmed, and it has been shown by cotransfection experiments that
GSK-3 can inhibit AP-1 activity in intact cells (35). These
results support the hypothesis that GSK-3 is an important regulator of
AP-1 in vivo.
We have demonstrated here that adhesion to FN activates ILK and
consecutively inhibits GSK-3, leading to higher AP-1 activity. The PI
3-kinase-dependent activation of AP-1 by ILK via GSK-3 could explain
why the overexpression of ILK in epithelial cells suppresses
suspension-induced apoptosis and stimulates anchorage-independent cell
cycle progression (40). This is concomitant with the higher AP-1 activity observed in ILK-13 cells, although c-jun protein expression is not increased. Overexpression of ILK leads to increased cyclin D1 and cyclin A, to activated cyclin D1-cdk4 and cyclin E-cdk2
kinases resulting in the hyperphosphorylation of the retinoblastoma protein (pRB) (40), and to the promotion of
anchorage-independent cell growth. It has recently been shown that
interactions between c-jun and pRB, two components regulated by ILK,
may represent an important mechanism for controlling transcription,
cell growth, and differentiation (36). GSK-3 is an important
molecule in the regulation of cell proliferation and cell survival.
Active GSK-3 can induce apoptosis (38), and it is also
implicated in the regulation of -catenin and cyclin D1, resulting in
their degradation (17, 34).
Our work emphasizes that although growth factors and the extracellular
matrix can regulate AP-1 via JNK activation, the involvement of ILK and
GSK-3 also appears to be required for extracellular matrix stimulation
of AP-1 activity.
| |
ACKNOWLEDGMENTS |
We thank Jim Woodgett and Jasbinder Sanghera for valuable
discussions. We also thank Jim Woodgett for providing the GSK-3 and
AKT-KD plasmids.
This work was supported by grants from the National Cancer Institute of
Canada and Kinetek Pharmaceuticals, Inc., to S.D.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: BC Cancer
Agency, Jack Bell Research Centre, 2660 Oak St., Vancouver, BC
V6H 3Z6, Canada. Phone: 604-875-5655. Fax: 604-875-5452. E-mail:
sdedhar{at}interchange.ubc.ca.
| |
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Abstract
Introduction
