(Received for publication, August 1, 1995; and in revised form, September 11, 1995)
From the
The PAK family of protein kinases has been suggested as a potential target of the Cdc42 and Rac GTPases based on studies in vitro. We show that PAK-3 is activated by Cdc42 in vivo. Both, activated (GTPase-defective) Cdc42 and a constitutively active PAK-3 mutant stimulated the activity of Jun kinase 1 (JNK1) in transfected cells. Activated Cdc42 also stimulated the activity of the related p38 mitogen-activated protein kinase but was a less effective activator of ERK2. The effect of Cdc42 on JNK activity was similar to that of the potent inflammatory cytokine interleukin-1 (IL-1). The observation that a dominant-negative Cdc42 mutant inhibited IL-1 activation of JNK1 indicates a role for Cdc42 in IL-1 signaling. These results suggest that Cdc42 and PAK may mediate the effects of cytokines on transcriptional regulation.
The Ras-like GTP-binding protein Cdc42, a member of the Rho family, plays an important role in the initiation of cytoskeletal alterations and in the establishment of cell polarity(1) . In Saccharomyces cerevisiae, this is manifested by the assembly of the bud site(2) , while in Schizosaccharomyces pombe Cdc42 is essential for both unidirectional and bidirectional cell growth(3) . Moreover, Cdc42 has recently been implicated in cell polarity-dependent processes that are critical to T cell activation (4) and the formation of filopodia in fibroblasts(5, 6) . Other members of the Rho family, Rac and Rho, promote formation of lamellipodia and actin stress fiber assembly, respectively(7, 8) . Indeed, Cdc42 may lie upstream from Rac and RhoA in growth factor-stimulated rearrangements of the cytoskeleton(5, 6, 8) . A key question concerns the identity of the cellular targets for Cdc42 and how the stimulation of these targets coordinate cytoskeletal changes and cell polarity-dependent processes with cell cycle events occurring in the nucleus.
A potential target of Cdc42 was identified as a
serine/threonine protein kinase, termed p65 PAK (p21 activated
kinase)(9) . Recently, we and others have cloned other closely
related kinases pointing to the existence of a family of PAKs, which
are activated by the GTPases Cdc42 and Rac in
vitro(10, 11) . ()The PAK family of
protein kinases is homologous to the yeast Ste20 protein kinase. Ste20
acts at an early step in a signaling pathway leading from a
receptor-activated heterotrimeric G protein to the MAP (
)kinases KSS1 and FUS3 in the response to mating
pheromone(12) . Indeed, we have shown that mPAK-3 can partially
restore the Ste20 null defect in S. cerevisiae(11) .
It is therefore possible that PAK may function upstream of MAP kinases
in mammalian signaling pathways. A mammalian protein kinase cascade
initiated by activated Ras, involving Raf and MAP kinase kinase (MEK)
and leading to activation of the MAP kinases ERK1 and ERK2 in response
to growth factors, is well established(13, 14) .
However, the Ras-dependent and -independent pathways leading to
activation of the JNK group of MAP kinases(15, 16) ,
which phosphorylate and activate the c-Jun transcription factor, have
not been fully elucidated(17) . Components of the JNK protein
kinase cascade that have been identified include the MAP kinase kinase
MKK4 (also designated SEK1/JNKK) (18, 19, 20) and the MAP kinase kinase kinase
MEKK1(21, 22) . The components of the JNK pathway
upstream of MEKK1 may include Ras (23) and/or additional
protein kinases. The purpose of this study was to evaluate the possible
role of Cdc42 and PAK as regulators of mammalian MAP signal
transduction pathways.
mPAK-3 immunoprecipitates were washed in 2
phosphorylation buffer (10 mM MgCl
and 40 mM Hepes (pH 7.4)) and divided into three equal aliquots. One aliquot
was subjected to Western blot analysis. The remaining aliquots were
mixed with or without Cdc42L61 (
5 µg) and 5 µg of the
substrate myelin basic protein (MBP) (Sigma). Kinase assays were
initiated by the addition of 10 µCi of
[
-
P]ATP (3000 Ci/mmol) and 20 µM ATP in 30 µl (final volume) for 10 min at 22 °C.
JNK,
ERK2, and p38 MAP kinase immunoprecipitates were incubated with 20
µM ATP, 5 µCi of [-
P]ATP
in 30 µl of kinase buffer (20 mM MgCl
, 25
mM Hepes (pH 7.6), 20 mM
-glycerophosphate, 20
mMp-nitrophenyl phosphate, 0.1 mM
Na
VO
, and 2 mM dithiothreitol). JNK
assays were performed with 3 µg of substrate GST-Jun(19) ,
ERK2 assays were performed using 3 µg of GST-Myc(36) , and
p38 MAP kinase assays were performed using 3 µg of GST-ATF2 (27) as substrates. The kinase reactions were terminated after
20 min at 22 °C with EDTA containing Laemmli sample buffer, and the
products were resolved by SDS-PAGE (12.5% gel). In control experiments,
the phosphorylation reaction was shown to be linear up to 30 min. The
incorporation of
P was visualized by autoradiography and
by PhosphorImager analysis (Molecular Dynamics). The protein kinase
activities of ERK2 and p38 MAP kinase were measured using the same
procedure.
To determine whether mPAK-3 is a target of Cdc42 in vivo, we examined the effect of the GTPase-defective Cdc42L61 mutant on mPAK-3 activity by co-transfection in COS1 cells (Fig. 1, A and B). HA-tagged mPAK-3 was immunoprecipitated from COS cells expressing HA-mPAK-3 together with Cdc42L61 (Fig. 1B, lane 1) or from cells expressing HA-mPAK-3 alone (Fig. 1B, lane 2). Expression of constitutively activated Cdc42L61 caused a marked stimulation of mPAK-3 protein kinase activity measured using MBP as a substrate (Fig. 1A). mPAK-3 autophosphorylation was not detected. This is probably due to phosphorylation of the major autophosphorylation site(s) in COS1 cells. However, in vitro studies demonstrate that mPAK-3 autophosphorylation is detectable and stimulated by recombinant Cdc42L61(11) .
Figure 1:
Cdc42
stimulates mPAK-3 protein kinase activity in vivo. A,
COS1 cells were transfected with plasmid J3HmPAK-3 expressing HA-tagged
WT mPAK-3 together with plasmid pcDNA3Cdc42L61 (lane 1) or
with J3HmPAK-3 alone (lane 2). The mPAK-3 proteins were
isolated by immunoprecipitation using the 12CA5 mAb. mPAK-3 protein
kinase activity was measured in the immune complex using
[-
P]ATP and MBP as substrates. The reaction
was terminated after 10 min, and the products of the phosphorylation
reaction were visualized after SDS-PAGE by autoradiography. B,
the mPAK-3 immunoprecipitates of COS cell lysates expressing HA-mPAK-3
and Cdc42L61 (lane 1) or HA-mPAK-3 (lane 2) were
examined by immunoblot analysis and probed with the 12CA5 mAb to detect
HA-mPAK-3 followed by chemiluminescence. Molecular mass standards
(kilodaltons) are indicated.
It has been
established that MAP kinase signal transduction pathways require
specific protein-protein interactions for normal function(17) .
Therefore, in initial studies to investigate the role of Cdc42, we
examined the complexes formed between Cdc42 and components of MAP
kinase cascades. Immunoblot analysis demonstrated the
GTPS-dependent association of PAK (
66 kDa) and MEKK (
78
and
200 kDa) with immobilized Cdc42. (
)Given that MEKK1
functions as an upstream kinase in the JNK MAP kinase
pathway(21, 22) , the observation of direct or
indirect GTP
S-dependent association of MEKK with Cdc42 complexes
pointed to the involvement of Cdc42 in a signaling pathway that
activates the JNK group of MAP kinases.
To test whether Cdc42 activates JNK, we expressed wild type (WT) Cdc42 or activated Cdc42L61 in COS1 cells and measured JNK protein kinase activity using GST-Jun as a substrate (Fig. 2). Activated, but not WT, Cdc42 stimulated JNK activity (Fig. 2, compare lanes 1 and 4) to an extent that was similar to that caused by the potent inflammatory cytokine IL-1 (Fig. 2, lane 2). Interestingly, a dominant-negative mutant of Cdc42 (Cdc42N17) was able to block IL-1 activation of JNK (Fig. 2, lane 6), indicating that endogenous Cdc42 may have a role in the IL-1 signaling pathway that causes JNK activation. These data establish Cdc42 as an activator of the JNK signal transduction pathway and are consistent with recent findings from other laboratories (28, 29) .
Figure 2:
Cdc42 stimulates JNK activity in
vivo. COS1 cells were transfected with plasmid pcDNA3-Flag-JNK1
together with an empty expression vector (lanes 1 and 2) or an expression vector encoding Cdc42 (lane 3),
Cdc42L61 (lane 4), Cdc42N17 (lanes 5 and 6).
Some cultures were treated with IL-1 (lanes 2 and 6).
The JNK activity was measured by immune complex kinase assays using
[-
P]ATP and c-Jun as substrates. The
products of the phosphorylation reaction were visualized after SDS-PAGE
by PhosphorImager analysis (Molecular Dynamics) and quantitated. The
relative incorporation of
P
in c-Jun was 1,
4.6, 0.6, 4.1, 0.007, and 0.6 for lanes 1-6,
respectively. Molecular mass standards (kilodaltons) are
indicated.
To
determine whether mPAK-3 is an intermediate in a Cdc42-initiated
signaling pathway leading to JNK1 activation, we created a
constitutively activated mPAK-3 protein kinase. The putative Cdc42/Rac
binding domain (designated PBD) is highly conserved among the mammalian
PAK family members including rat p65PAK, hPAK-1, hPAK-2, and mPAK-3 (9, 10, 11) . The region of rat
p65PAK (amino acids 67-150), which binds to Cdc42 and Rac, is
conserved in mPAK-3 (residues 67-137) and mediates the binding of
mPAK-3 to Cdc42 and Rac in vitro. (
)Since the
binding of Cdc42 to mPAK-3 stimulates PAK protein kinase
activity(11) , it is possible that Cdc42 binding relieves a
negative constraint conferred by an intramolecular interaction between
the PBD and another subregion of the PAK protein kinase. This
hypothesis suggests that mutations in the PBD may cause activation of
PAK protein kinase activity by relieving this negative constraint. We
made three mutations in the PBD of mPAK-3 (F91S, G93A, and P95A). The
protein kinase activity of WT and PBD-mutated mPAK-3 was examined in an
immune complex kinase assay (Fig. 3A); Fig. 3B shows the relative expression of wild type and
PBD-mutated mPAK-3. The WT mPAK-3 protein kinase was activated by the
addition of Cdc42L61 (Fig. 3A, compare lanes 1 and 2). In contrast, the PBD-mutated mPAK-3 exhibited a
high basal protein kinase activity that was not further activated by
Cdc42L61 (Fig. 3A, compare lanes 3 and 4). These data establish that the PBD-mutated mPAK-3 is
constitutively activated in vitro.
Figure 3:
PBD-mutated mPAK-3 is constitutively
active. A, COS1 cells were transfected with plasmid expressing
WT HA-mPAK-3 (lanes 1 and 2) or PBD-mutated HA-mPAK-3 (lanes 3 and 4). The mPAK-3 proteins were isolated by
immunoprecipitation using the 12CA5 mAb. The HA-mPAK-3 immune complexes
were incubated with (lanes 2 and 4) or without (lanes 1 and 3) activated Cdc42L61 (5 µg).
The protein kinase activity was measured in the immune complex using
[
-
P]ATP and MBP as substrates. The reaction
was terminated after 10 min, and the products of the phosphorylation
reaction were visualized after SDS-PAGE by autoradiography. B,
whole cell lysates (WCL) and 12CA5 mAb immunoprecipitates (IP) isolated from untransfected COS1 cells (lane 1)
or COS cells transfected with WT HA-mPAK-3 (lanes 2 and 4), or PBD-mutated HA-mPAK-3 (lanes 3 and 5)
were examined by immunoblot analysis and probed with the 12CA5 mAb to
detect HA-mPAK-3. The highest molecular weight band observed in whole
cell lysates (see lanes 2 and 3) is also present in
untransfected COS cells (although it is not readily observed in lane 1). The molecular weight bands below 65 kDa detected in lane 3 likely represent proteolyzed forms of PBD-mutated
HA-mPAK-3. Molecular mass standards (kilodaltons) are
indicated.
To examine the possible role of mPAK-3 as a regulator of the JNK signal transduction pathway, we investigated the effect of WT and activated (PBD-mutated) mPAK-3 on JNK activity. Expression of WT mPAK-3 caused a small increase in JNK protein kinase activity compared with control cells transfected with the empty expression vector (Fig. 4, compare lanes 1 and 3). A larger increase in JNK protein kinase activity was detected in cells transfected with the activated (PDB-mutated) mPAK-3 (lane 4). Co-expression of activated mPAK-3 with activated Cdc42L61 (lane 6) did not cause JNK activation that was greater than that caused by Cdc42L61 alone (lane 5). The absence of additive JNK activation caused by Cdc42L61 and PDB-mutated mPAK-3 is consistent with the hypothesis that Cdc42 and mPAK-3 do not activate JNK through independent pathways. Instead, these data indicate that Cdc42 and mPAK-3 may function as components of the same signal transduction pathway that leads to JNK protein kinase activation.
Figure 4:
Activated PAK stimulates JNK protein
kinase activity in vivo. COS1 cells were transfected with
pcDNA3-Flag-JNK1 together with an empty expression vector (lanes 1 and 2) or an expression vector encoding mPAK-3 (lane
3), PBD mutant mPAK-3 (lane 4), Cdc42L61 (lane
5), Cdc42L61, and PBD-mutated mPAK-3 (lane 6). The JNK
activity was measured by immune complex kinase assays using
[-
P]ATP and c-Jun as substrates. The
products of the phosphorylation reaction were visualized after SDS-PAGE
by PhosphorImager analysis (Molecular Dynamics) and quantitated. The
relative incorporation of
P
in c-Jun was 1,
4.1, 1.3, 2.2, 4.8, and 4.5 for lanes 1-6, respectively.
Molecular mass standards (kilodaltons) are
indicated.
To address the specificity of MAP kinase activation by Cdc42, we compared the effect of activated Cdc42L61 on JNK and the related MAP kinases p38 (22, 24, 25) and ERK2(26) . Activated Cdc42L61 stimulated the activity of JNK (Fig. 5, lanes 3 and 4) and p38 MAP kinase (lanes 5 and 6). In contrast, Cdc42L61 caused only a small increase in the activity of ERK2 (lanes 1 and 2). Previous studies have demonstrated that JNK and p38 are similarly regulated(27) . The results of this study indicate that the Cdc42 signal transduction pathway leads to the selective activation of the JNK and p38 groups of stress-activated MAP kinases(17) . The activation of Cdc42 therefore represents one mechanism that may mediate the stimulation of JNK and p38 activity in response to different environmental stimuli.
Figure 5:
Cdc42 activates the JNK and p38 groups of
MAP kinases. COS1 cells were transfected with pCMV-HA-ERK2 (lanes 1 and 2)(32) , pcDNA3-Flag-JNK1 (lanes 3 and 4), and pCMV-Flag-p38 (lanes 5 and 6) together with an empty expression vector (lanes 1, 3, and 5) or an expression vector encoding Cdc42L61 (lanes 2, 4, and 6). The MAP kinase activity
was measured by immune complex kinase assays using
[-
P]ATP and the substrate c-Myc for ERK2,
c-Jun for JNK1, and ATF2 for p38 MAP kinase. The products of the
phosphorylation reaction were visualized after SDS-PAGE by
PhosphorImager analysis (Molecular Dynamics). Molecular mass standards
(kilodaltons) are indicated.
Cdc42 and Rac have been shown to activate PAK kinases(9, 10, 11) , indicating that both of these GTP-binding proteins may have a role in mediating signaling to JNK1 and/or p38 MAP kinases. While this paper was in preparation, Coso et al.(28) and Minden et al.(29) reported that the Cdc42 and Rac GTPases can cause JNK activation. The present study extends these findings by demonstrating that: 1) dominant-negative Cdc42 blocks the activation of JNK and p38 MAP kinases caused by the inflammatory cytokine IL-1; 2) Cdc42 activates mPAK-3 in vivo; and 3) constitutively active mPAK-3 causes JNK activation. These data indicate a role for Cdc42 and PAK in the IL-1 signaling pathway that leads to JNK and p38 activation. At present, the intermediate steps between Cdc42/PAK and JNK1 or p38 are unknown, although recent results suggest the possibility that MEKK (21, 22) and/or MAP kinase kinase (18, 19, 20) family members are downstream from Cdc42 and PAK. Taken together, these results (cf. (28) and (29) ) also support a possible connection between the actions of Dbl and related oncoproteins and nuclear MAP kinases. The Dbl (30) and Ost (31) oncoproteins serve as guanine nucleotide exchange factors for the Cdc42 and RhoA proteins while the product of the cell invasion gene tiam-1 is an exchange factor for Cdc42 and Rac(30) . An intriguing possibility is that the proliferative or invasive response of cells to these oncoproteins may be mediated by common signal transduction pathways leading to JNK and/or p38 MAP kinase activation.
Interestingly, Rac has recently been shown to be involved downstream of Ras in cellular transformation and to possess transforming activity itself(33) . It is therefore possible that Rac, and perhaps Cdc42, act downstream of Ras in the Ras-dependent pathway leading to JNK1/p38 activation. While it is well established that growth factor stimulation of Ras leads to the activation of the Raf/Mek/Erk pathway, it has become clear that Ras is involved in signaling to the cytoskeleton. A possible point of convergence between the Ras and Cdc42 signaling pathways is through the phosphatidylinositol 3-kinase, which has been implicated in cytoskeleton signaling and shown to bind to both of these GTPases(34) . Therefore, these findings suggest that signaling pathways through the Ras and Cdc42 GTPases are orchestrated to yield a coordinated response of cytoskeletal and nuclear events to stress, cytokines, and growth factors.