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Molecular and Cellular Biology, October 2000, p. 7160-7169, Vol. 20, No. 19
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Vav2 Activates Rac1, Cdc42, and RhoA Downstream
from Growth Factor Receptors but Not 
1 Integrins
Betty P.
Liu1,* and
Keith
Burridge1,2
Department of Cell Biology and
Anatomy1 and Lineberger Comprehensive
Cancer Center,2 University of North Carolina
at Chapel Hill, Chapel Hill, North Carolina
Received 22 February 2000/Returned for modification 24 April
2000/Accepted 6 July 2000
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ABSTRACT |
The Rho family of GTPases plays a major role in the organization of
the actin cytoskeleton. These G proteins are activated by guanine
nucleotide exchange factors that stimulate the exchange of bound GDP
for GTP. In their GTP-bound state, these G proteins interact with
downstream effectors. Vav2 is an exchange factor for Rho family
GTPases. It is a ubiquitously expressed homologue of Vav1, and like
Vav1, it has previously been shown to be activated by tyrosine
phosphorylation. Because Vav1 becomes tyrosine phosphorylated and
activated following integrin engagement in hematopoietic cells, we
investigated the tyrosine phosphorylation of Vav2 in response to
integrin-mediated adhesion in fibroblasts and epithelial cells. However, no tyrosine phosphorylation of Vav2 was detected in response to integrin engagement. In contrast, treating cells with either epidermal growth factor or platelet-derived growth factor stimulated tyrosine phosphorylation of Vav2. We have examined the effects of
overexpressing either wild-type or amino-terminally truncated (constitutively active) forms of Vav2 as fusion proteins with green
fluorescent protein. Overexpression of either wild-type or
constitutively active Vav2 resulted in prominent membrane ruffles and
enhanced stress fibers. These cells revealed elevated rates of cell
migration that were inhibited by expression of dominant negative forms
of Rac1 and Cdc42. Using a binding assay to measure the activity of
Rac1, Cdc42, and RhoA, we found that overexpression of Vav2 resulted in
increased activity of each of these G proteins. Expression of a
carboxy-terminal fragment of Vav2 decreased the elevation of Rac1
activity induced by epidermal growth factor, consistent with Vav2
mediating activation of Rac1 downstream from growth factor receptors.
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INTRODUCTION |
The Rho family of GTP-binding
proteins regulates many important cellular processes, such as cell
migration, the organization of the cytoskeleton, cell-matrix and
cell-cell adhesion, cell cycle progression, and gene expression
(22, 44, 50). At present, 14 members of the Rho family have
been identified in mammalian cells (55), but most attention
has been directed towards three widely expressed members, RhoA, Rac1,
and Cdc42. These three proteins have both unique and overlapping
functions. In terms of cell migration and cytoskeletal organization,
they regulate distinct processes: Cdc42 controls the assembly of
filopodia (28, 33), Rac1 stimulates the formation of
lamellipodia and membrane ruffles (42), and RhoA regulates
the assembly of stress fibers (41). Like other G proteins,
Rho family members act as molecular switches and are active with GTP
bound and inactive with GDP bound. The switch between these states is
regulated by guanine nucleotide exchange factors (GEFs), which exchange
GDP for GTP, and by GTPase activating proteins (GAPs), which stimulate
the endogenous GTPase activity of these proteins, resulting in
hydrolysis of the bound GTP (22, 50). In turn, the
activities of these GEFs and GAPs are regulated by various signaling
pathways that are initiated by ligand binding to cell surface
receptors. Both soluble agents, such as growth factors (24, 35,
41, 42), and extracellular matrix (ECM) proteins (5, 14, 38,
40) have been shown to activate Rho family members. Some of the
steps in these signaling pathways remain to be elucidated.
Specifically, many of the GEFs that mediate activation of Cdc42, Rac1,
and RhoA downstream from surface receptors have not been identified.
One of the best characterized GEFs is Vav1, which is restricted in its
distribution to hematopoietic cells (8, 9). Vav1 has been
shown to act on Rac1, Cdc42, and RhoA in vitro (16, 23, 36,
46). The exchange factor activity of Vav1 is regulated by
tyrosine phosphorylation (16, 23), and numerous studies have
revealed that Vav1 is rapidly tyrosine phosphorylated in response to
diverse stimuli (reviewed in reference 9). For example, Vav1 becomes tyrosine phosphorylated following ligation of T-
and B-cell receptors and in response to many different cytokines and
growth factors binding to their receptors (8, 9). In several
situations, engagement of specific integrins has also been shown to
stimulate Vav1 tyrosine phosphorylation. This has been observed
following antibody ligation of 
2 integrins in human neutrophils
(54), following antibody ligation of 1 integrins in
myeloid cells (20), and in platelets as they adhere to
fibrinogen via the integrin 
IIb3 or to collagen or fibronectin
via 1 integrins (12). Pursuing the pathway from
IIb3 engagement to Vav1 activation, Miranti and coworkers were
able to reconstitute Vav1 activation in CHO cells by coexpressing
IIb3, Vav1, and the tyrosine kinase Syk (31). Previous
work had identified Syk as a tyrosine kinase that becomes rapidly
activated in response to IIb3 engagement in platelets,
independent of the activation of the focal adhesion kinase (FAK)
(15, 18), a tyrosine kinase that is prominently activated
following integrin-mediated adhesion (21, 29). In another
study, expression of Vav1 in CHO cells resulted in its tyrosine
phosphorylation in response to 1 integrin-mediated adhesion. This
was accompanied by increased stress fibers and lamellipodia, consistent
with Vav1-mediated activation of RhoA and Rac1 (53).
Due to its hematopoietic cell-specific expression, Vav1 cannot be
responsible for integrin-mediated activation of Rho family G proteins
in other cell types. The discovery of a more ubiquitously distributed
isoform, Vav2 (25, 45), provided a candidate GEF that may
act downstream from integrins in nonhematopoietic cells. The objective
of this study was to determine whether Vav2 was tyrosine phosphorylated
and consequently activated in response to 1 integrin engagement and
to determine which Rho family members are activated by Vav2. We found
that unlike Vav1, Vav2 is not tyrosine phosphorylated following
integrin-mediated cell adhesion to ECM. However, we have found that it
is tyrosine phosphorylated in response to the growth factors epidermal
growth factor (EGF) and platelet-derived growth factor (PDGF).
Moreover, expression of a dominant negative Vav2 construct was found to
diminish the elevation in Rac1 activity induced by EGF, suggesting that
Vav2 contributes to Rac1 activation in response to growth factor
stimulation of cells. Examination of actin cytoskeletal structures in
cells transfected with an activated form of Vav2 revealed extensive lamellipodia and membrane ruffles but also prominent stress fibers. The
observed effects on the cytoskeleton prompted investigation of a role
for Vav2 in cell motility. Cells expressing activated Vav2 exhibited
enhanced motility that could be blocked by dominant negative forms of
Rac1 or Cdc42. These findings indicated that Vav2 may act on Rac1,
Cdc42, and RhoA in vivo. An assay to specifically detect GTP-bound
versions of these proteins confirmed that activated Vav2 increases the
intracellular levels of active Rac1, Cdc42, and RhoA.
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MATERIALS AND METHODS |
Mammalian expression vectors.
Full-length human Vav2 cDNA
was the generous gift of David Kwiatkowski (25). To generate
Vav2 constructs that were fused with green fluorescent protein (GFP),
Vav2 DNA constructs were engineered to contain an EcoRI
restriction site at the 5' end and a HindIII restriction
site at the 3' end to allow for directed subcloning into the multiple
cloning site in the mammalian expression vector, pEGFP-N1 (Clontech,
Palo Alto, Calif.). To ligate the N-terminally truncated Vav2 (amino
acids [aa] 184 to 878) to the pEGFP vector, a
HindIII-EcoRI fragment was amplified from
human Vav2 cDNA with oligonucleotides 5' AAG GTG AAG CTT CAG CGC GCC ATG ATT AGA TAC 3' and 5' CTG AAT TCG CTG GAT GCC CTC CTC 3' by PCR
using Pfu Turbo polymerase (Stratagene, La Jolla, Calif.). A
C-terminal Vav2 construct (aa 594 to 878) was amplified using oligonucleotides 5' CCC AAG CTT GGC GCC ATG CAG AAT TAC CAT 3' and 5'
CTG AAT TCG CTG GAT GCC CTC CTC 3'. All constructs were designed with a
Kozak sequence and ATG to be in frame with GFP on the pEGFP-N1 vector.
All PCR-generated fragments were sequenced to confirm that no errors
were introduced during PCR.
Antibodies.
To generate polyclonal antibodies against Vav2,
rabbits were immunized with recombinant Vav2 proteins fused to
glutathione-S-transferase (GST). To this end, human Vav2
cDNA was used as the template for a PCR that generated the C-terminal
of Vav2, consisting of the Src homology 3 (SH3)-SH2-SH3 domains (aa 574 to 876). The primers 5' CCC TGG AAT TCC ATC TCT CCT GCA GAT CTG 3' and
5' TCA CTG AAT TCC CTC CTC TTC TAG GTA CGT TGA AGG AAA 3' were used.
The PCR product (925 bp) was designed to contain EcoRI
restriction sites at both the 3' and 5' end to allow for subcloning
into the bacterial expression vector, pGEX-4T3 (Amersham Pharmacia
Biotechnology, Piscataway, N.J.). The resulting GST-Vav2 (SH3-SH2-SH3)
fusion protein was expressed in Escherichia coli DH5.
After overnight induction with
isopropyl--D-thiogalactopyranoside (IPTG) at 25°C, bacteria were resuspended in Tris-buffered saline (TBS) with 1% Triton
X-100 and lysed by sonication. Fusion proteins were purified by
chromatography on glutathione-Sepharose (Amersham Pharmacia Biotechnology) from clarified bacterial lysates and concentrated with
Centricon concentrators (Amicon Inc., Beverly, Mass.). Aliquots (0.5 to
1 mg) of fusion protein were used to immunize rabbits. After a series
of immunizations, a high-titer antiserum was obtained that interacted
with Vav2. This rabbit antiserum was used at 1:20,000 for immunoblotting.
Cell culture.
NIH 3T3 and BALB/c3T3 fibroblasts were
cultured at 37°C with 10% CO2 in Dulbecco's modified
Eagle's medium (DMEM) with high glucose, supplemented with 10% bovine
calf serum. CHOK1 and HEK293 cells were cultured at 37°C with 10 and
5% CO2, respectively, in DMEM supplemented with 10% fetal
bovine serum. All media contained penicillin G (100 U/ml), streptomycin
sulfate (100 µg/ml), and amphotericin B (25 µg/ml). Culture media
for CHO cells contained additional 1 mM MEM nonessential amino acids
(Life Technologies, Grand Island, N.Y.).
Transient transfection.
Lipofectamine Plus was obtained from
Life Technologies and used for transfection of NIH 3T3, BALB/c3T3,
HEK293, and CHO cells essentially according to the manufacturer's
instructions. Briefly, 106 cells were plated on
100-mm-diameter tissue culture dishes 18 to 24 h prior to
transfection. Four micrograms of the various Vav2 DNA constructs or
vector alone and 20 µl of Plus reagent as well as 30 µl of
Lipofectamine were added to each plate in 1.5 ml of DMEM. After 2 h, cells were washed once with DMEM and cultured in their regular
medium. Cells were used for various assays at 24 to 48 h posttransfection.
Migration assay.
To assess the migratory behavior of cells
transfected with various Vav2 DNA constructs, we performed migration
assays using a Transwell cell culture chamber containing polycarbonate
membrane inserts with 8-µm pores (Corning Costar Corp., Cambridge,
Mass.). The undersides of the porous membranes were coated with
fibronectin at 10 µg/ml in Dulbecco's phosphate-buffered saline
(PBS) for 1 h at 37°C and then blocked with 2% bovine serum
albumin in PBS for 0.5 h at room temperature. After blocking,
membranes were rinsed with PBS for 5 min and 500 µl of DMEM was added
to the lower chamber. Transfected cells (105) were plated
into each chamber in DMEM and allowed to migrate through the pores for
2 h. Cells that migrated through the membrane were detected by
staining for actin, by GFP fluorescence or, in the case of cells
expressing myc-tagged dominant negative constructs of Rac1 and Cdc42,
by immunostaining for myc.
Immunoprecipitation and immunoblotting.
HEK293 or NIH 3T3
cells were washed with PBS and lysed in modified RIPA buffer (25 mM
Tris [pH 7.4], 150 mM NaCl, 10 mM MgCl2, 2 mM EGTA,
0.02% sodium dodecyl sulfate [SDS], 0.2% deoxycholate, 1% NP-40)
for 5 min on ice. Lysates were clarified by centrifugation at
12,000 × g for 10 min. Protein concentrations were
measured using the Coomassie protein assay reagent, with bovine serum
albumin as a standard, following the manufacturer's instructions
(Pierce, Rockford, Ill.). Vav2 was immunoprecipitated from cell lysates (1 mg of protein), using 2 µl of Vav2 rabbit antiserum.
Immunoprecipitates were collected by incubating with protein
A-Sepharose (Sigma, St. Louis, Mo.) for 1 h at 4°C. The
immunoprecipitates were washed three times with modified RIPA buffer
and bound proteins were eluted by boiling in SDS-polyacrylamide gel
electrophoresis sample buffer. Immunoprecipitates and cell lysates were
analyzed on SDS-polyacrylamide gels and then transferred to
nitrocellulose membranes. Blotting was performed as described
previously. Peroxidase-conjugated secondary antibodies were from
Chemicon (Temecula, Calif.). Blots were developed using SuperSignal
Substrate for Western blotting (Pierce) and then exposed to Kodak
Scientific Image film.
Activity assays for Rac1, Cdc42, and RhoA.
The assay of Rac1
activity was performed as previously described (4) with some
modifications. Cells were first rinsed once with 20 mM HEPES, pH 7.4, and 150 mM NaCl and then lysed in RIPA buffer with 500 mM NaCl and
protease inhibitors. GTP-bound Rac1 (i.e., activated Rac1) was affinity
precipitated from cell lysates (350 to 500 µg of protein) using an
immobilized GST fusion construct of the Rac1 binding domain of murine
p65Pak (the p21Rac binding domain [PBD]) that binds to
Rac1-GTP but not to Rac1-GDP (3). The GST-PBD construct was
kindly provided by R. A. Cerione and S. Bagrodia (Cornell
University, Ithaca, N.Y.). Rac1 that sedimented with the GST-PBD beads
was separated using SDS-polyacrylamide gel electrophoresis transferred
to polyvinylidene difluoride membrane and blotted with an antibody
against Rac1 (Transduction Labs, San Diego, Calif.). Cdc42-GTP binds to
the same PBD construct (3) and so the same assay was used to
measure Cdc42 activity, except that the blots were probed with an
antibody against Cdc42 (Transduction Labs). Essentially the same assay was used to measure RhoA-GTP, except for these assays, the RhoA binding
domain (RBD) of Rhotekin (40) was used as a GST construct (kindly provided by L. Petch, University of North Carolina at Chapel
Hill). RhoA that sedimented with the GST-RBD beads was detected with an
antibody against RhoA (Transduction Labs).
Quantitation of bands on immunoblots was performed using Metamorph
software (Universal Imaging, Westchester, Pa.). Films were scanned with
a ScanJet 6100C film scanner, and the images were imported into
Metamorph for quantitation. For each pulldown assay, the level of
GTPase sedimented was normalized relative to the amount of the GTPase
in the cell lysate. This was done to avoid errors arising from
different levels of expression of the GTPases in different samples.
For some experiments (see Fig.
8), quantitation of Rac1 activity was
performed using phosphorimager analysis of immunoblots.
For these
experiments, blots were developed using enhanced chemifluorescence
(Amersham Life Sciences, Little Chalfont, Buckinghamshire, United
Kingdom). Blots were scanned with a Storm phosphorimager under
blue
fluorescence. Quantitation of band intensities was performed
using
ImageQuant. Statistical significance was calculated using
the Student
two-sample
t test.
P values of <0.05 were
considered
significant.
Immunofluorescence.
Cells were processed for
immunofluorescence microscopy as previously described (30).
Briefly, cells were fixed in 3.7% formaldehyde in PBS for 10 min,
rinsed in TBS at pH 7.6 for 3 min, and then permeabilized for 8 min in
TBS containing 0.5% Triton X-100. Expression of the various Vav2-GFP
constructs was determined by GFP fluorescence. Actin was visualized
using phalloidin labeled with Texas red (Molecular Probes, Eugene,
Oreg.). Microscopy was performed on a Zeiss Axiophot microscope. Images
were acquired with a MicroMAX 5 MHz cooled charge-coupled device camera
(Princeton Instrument, Trenton, N.J.) and processed using Metamorph
Image software (Universal Imaging).
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RESULTS |
Vav2 is tyrosine phosphorylated in response to growth factors but
not in response to extracellular matrix.
Integrin-mediated cell
adhesion results in tyrosine phosphorylation of several signaling
molecules, such as FAK, paxillin, and p130Cas (2, 7, 13,
47). To determine if Vav2 becomes tyrosine phosphorylated during
integrin-mediated adhesion, Vav2 was immunoprecipitated from
serum-starved HEK293 cells that were either held in suspension or
allowed to attach and spread on fibronectin for times of 10, 20, 30, or
60 min. The immunoprecipitated Vav2 was analyzed for the presence of
phosphotyrosine by immunoblotting (Fig.
1a). Low levels of phosphotyrosine were
detected in Vav2 from cells in suspension and those adhering to
fibronectin at all time points, but no increase in Vav2 tyrosine
phosphorylation was detected in response to adhesion. Similarly, Vav2
tyrosine phosphorylation was not observed in response to adhesion to
collagen (data not shown). In addition, no stimulation of Vav2 tyrosine phosphorylation was observed when NIH 3T3 cells were plated on fibronectin (data not shown).
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FIG. 1.
Vav2 is tyrosine phosphorylated in response to growth
factors but not in response to adhesion to ECM. (a) Upper panel:
antiphosphotyrosine blot of endogenous Vav2 immunoprecipitated from
HEK293 cells held in suspension (S) or plated on fibronectin (Fn) for
10, 20, 30, or 60 min. Bottom panel: the blot was stripped and reprobed
for Vav2 with an anti-Vav2 antibody to compare the amounts of Vav2
immunoprecipitated for each time point. (b) Upper panel:
antiphosphotyrosine blot of Vav2 immunoprecipitated from serum-starved
HEK293 cells that were treated with EGF (100 ng/ml) for 0, 5, 10, 20, 30, 40, or 60 min. Bottom panel: the amount of Vav2 protein
immunoprecipitated was compared by stripping the blot and reprobing
with anti-Vav2 antibody. (c) Vav2 is tyrosine phosphorylated in
response to PDGF-BB. NIH 3T3 cells were treated for 0, 10, and 20 min
with PDGF-BB (50 ng/ml). Vav2 was immunoprecipitated and blotted for
phosphotyrosine (upper panel), and Vav2 (lower panel).
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Exploring other factors that might stimulate the tyrosine
phosphorylation of Vav2, serum-starved, adherent HEK293 cells were
treated with EGF (100 ng/ml) for 0, 5, 10, 20, 30, 40, or 60 min,
and
Vav2 was immunoprecipitated and analyzed by blotting with
antiphosphotyrosine (Fig.
1b). Under these conditions, Vav2 revealed
robust tyrosine phosphorylation, which had already peaked by 5
min of
stimulation with EGF. Densitometric analysis of the phosphotyrosine
blot revealed that the level of phosphotyrosine in Vav2 was elevated
approximately sevenfold at the 5-min time point. At 60 min of
EGF
stimulation, the level of phosphotyrosine in Vav2 had decreased
to
twofold above the unstimulated level. To examine whether other
growth
factors also stimulated Vav2 tyrosine phosphorylation,
NIH 3T3 cells
were treated with PDGF-BB (50 ng/ml), and Vav2 was
immunoprecipitated
and analyzed for phosphotyrosine by blotting
(Fig.
1c). Again, tyrosine
phosphorylation was observed in response
to this growth factor
(fourfold elevation in phosphotyrosine at
10 min of PDGF treatment),
but the phosphorylation was more transient
than that induced by EGF,
and by 20 min it had decreased to just
twofold above the background
level. Previous work has demonstrated
that the exchange factor activity
of Vav2 (like that of Vav1)
is regulated by tyrosine phosphorylation
(
46), suggesting that
Vav2's exchange factor activity is
downstream of soluble growth
factors but not downstream of
1
integrin engagement. We also
examined whether the tyrosine
phosphorylation of Vav2 induced
by growth factors was affected by cell
adhesion to ECM. We observed
that EGF treatment of either suspended or
adherent cells both
resulted in elevated tyrosine phosphorylation of
Vav2 (data not
shown).
Wild-type and N-terminally truncated Vav2 induce membrane ruffling
and lamellipodia in fibroblasts.
In order to study the activity of
Vav2 in cells, we generated a set of Vav2 constructs (Fig.
2), each one fused to GFP at the carboxy
terminus so that the expression of the constructs could be monitored in
live cells. These constructs included wild-type Vav2, a construct in
which the amino-terminal calponin homology (CH) domain and acidic
domain (AD) are deleted (
184N Vav2), and a construct consisting of
the carboxy-terminal SH2 domain flanked by the two SH3 domains
(SH3-SH2-SH3). Previous work has shown that deletion of the
amino-terminal CH domain and AD results in a form of Vav2 that is
constitutively active in vitro with respect to exchange factor activity
and that expression of such mutants is a potent inducer of
transformation in NIH 3T3 cells (1, 45, 46).
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FIG. 2.
Schematic representation of Vav2 fusion proteins used in
this paper. Each construct was fused at the C terminus to GFP. The
domains indicated are the CH, AD, Dbl homology (DH), pleckstrin
homology (PH), SH3, and SH2 domains. 184N is a constitutively
active, amino-terminally truncated version of Vav2 that lacks the CH
domain and AD. The carboxy-terminal mutant contains only the SH2 domain
flanked by the two SH3 domains.
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To examine the effect of these GFP-tagged Vav2 constructs on cell
morphology, cytoskeletal organization, and cell migration,
the
constructs were expressed in a variety of cell types using
transient
transfection. Expression of either wild-type Vav2 or
184N resulted
in a reorganization of actin in NIH 3T3 and BALB/c3T3
cells (Fig.
3). (These cell types were used because
of their well-spread
morphology, prominent stress fibers, and ability
to develop easily
visualized membrane ruffles.) Both constructs induced
extensive
membrane ruffling and lamellipodial extension. In general,
184N
Vav2 was more potent and often generated broad lamellipodia
that
extended around much of the cell margin (Fig.
3 E to H). Many
cells expressing wild-type Vav2 or
184N Vav2 revealed stress
fibers
that were more prominent than the stress fibers of untransfected
cells
or cells transfected with GFP alone (Fig.
3A and B). No
significant
effects on morphology or actin organization were observed
in cells in
which the SH3-SH2-SH3 construct was expressed (data
not shown). We
examined the state of tyrosine phosphorylation
of the expressed
wild-type and
184N Vav2 constructs by immunoprecipitating
these from
cell lysates using an antibody against GFP. Immunoblotting
these
immunoprecipitates revealed that both the wild-type and
184N
Vav2-GFP constructs were tyrosine phosphorylated (data not
shown).
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FIG. 3.
The effects of Vav2 transient expression on the actin
cytoskeleton. NIH 3T3 cells (A to F) were transiently transfected with
GFP alone (A and B), with wild-type Vav2 as a GFP construct (C and D),
or with the 184N Vav2-GFP (E and F). BALB/c3T3 cells (G and H) were
transfected with 184N Vav2 as a GFP fusion protein. Transfected
cells were visualized for GFP (A, C, E, and G). The distribution of
actin was visualized by staining with phalloidin conjugated with Texas
red (B, D, F, and H). Note that expression of both wild-type and
184N Vav2 induced prominent lamellipodia and membrane ruffles.
Bar = 20µm.
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The above analysis was performed on transfected cells that were
maintained in the presence of serum. We wished to examine
the effects
of these Vav2 constructs on cells in the absence of
either serum or
growth factors. For these experiments, NIH 3T3
cells were transfected
and after 24 h were transferred to serum-free
conditions for an
additional 24 h before fixing and staining for
actin.
Nontransfected, serum-starved cells showed decreased stress
fibers and
no membrane ruffling activity (Fig.
4).
However, cells
overexpressing either wild-type Vav2 (Fig.
4A and B) or
184N
Vav2 (Fig.
4C and D) continued to reveal prominent stress
fibers
and membrane ruffles under serum-free conditions.
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FIG. 4.
The effects of Vav2 transient expression on actin
organization in serum-starved cells. NIH 3T3 cells were transiently
transfected with either wild-type Vav2-GFP (A and B) or 184N
Vav2-GFP (C, D). After 24 hours in the presence of serum, the cells
were starved for a further 24 hours before fixation and staining for
actin. The transfected cells are shown in A and C, the organization of
actin is shown in B and D. Bar = 20 µm.
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Cell migration is induced by Vav2 and can be blocked by N17Rac and
N17Cdc42.
The prominent membrane ruffling displayed by cells in
which wild-type Vav2 or 184N Vav2 was expressed indicated that these cells might display enhanced migratory behavior. To explore the effects
of Vav2 on cell migration, we used a Transwell assay, in which the
lower surface of a porous polycarbonate membrane was coated with
fibronectin and the number of cells migrating through the membrane
after 2 h under serum-free conditions was determined by counting.
For these experiments, the 184N Vav2 construct was used because of
its higher potency. Migration was assayed using CHO cells because of
their high transfection efficiency and because their migratory activity
is easily determined using Transwell filters. Expression of 184N
Vav2 in CHO cells resulted in an approximately twofold increase in the
number of cells migrating through the Transwell filter compared with
untransfected cells or cells expressing GFP only (Fig.
5). To explore whether this stimulation
of cell migration involved Rac1 or Cdc42, cells were cotransfected with
184N Vav2 and dominant negative versions of Rac1 (N17Rac1) or Cdc42
(N17Cdc42). Coexpression of either N17Rac1 or N17Cdc42 blocked the
increase in migration induced by 184N Vav2 (Fig. 5). In addition,
cotransfection of N17Rac1 or N17Cdc42 blocked the morphological
phenotype of prominent membrane ruffles and lamellipodia in CHO cells
expressing 184N Vav2 (Fig. 6). Coexpression of the dominant negative constructs did not alter the
level of expression of 184N Vav2 (data not shown).
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FIG. 5.
Constitutively activated Vav2 induced an increase in
cell migration that was inhibited by dominant negative forms of Rac1
and Cdc42. Transwell assays were performed on CHO cells transiently
transfected with GFP alone, 184N Vav2-GFP alone, or 184N Vav2-GFP
cotransfected with myc-tagged N17Rac1 or N17Cdc42. Cells were plated on
the Transwell membrane in serum-free medium in the absence of ECM and
growth factors. The underside of the Transwell membrane was coated with
fibronectin (10 µg/ml). Cells migrating through the membrane in a 2-h
period were counted. The bar graph represents three separate
experiments (error bars, standard error of the mean). For the
inhibition of migration by N17Rac1, P = 0.015. For the
inhibition of migration by N17Cdc42, P = 0.005.
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FIG. 6.
Effect of coexpressing dominant negative Cdc42 and Rac1
on the morphology of cells expressing constitutively active Vav2. CHO
cells were transfected with 184N Vav2-GFP either alone (A and B) or
cotransfected with myc-tagged N17Cdc42 (C to E) or myc-tagged N17Rac1
(F to H). Actin was visualized by staining with rhodamine-phalloidin
(A, C, and F). Cells expressing 184N Vav2-GFP were visualized by GFP
fluorescence (B, D, and G). Cells expressing the myc-tagged constructs
were visualized by immunofluorescence (E and H). Bar = 20 µm.
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Vav2 increases Rac1, Cdc42, and RhoA activity.
The above
results suggest that Rac1, Cdc42, and RhoA are involved in the
Vav2-induced phenotype of increased migration and in the morphological
effects generated by Vav2 overexpression or activation. However, the
use of dominant negative Rho family members is indirect. These dominant
negative constructs work by competing with the endogenous G proteins
for binding to exchange factors (17, 50). Many GEFs activate
more than one Rho family member (10, 49, 51); therefore,
dominant negative forms of these G proteins may block the activity of a
related but distinct family member. Indeed, this probably accounts for
the inhibition of membrane ruffling by dominant negative N17Cdc42 noted
above. Consequently, we wished to measure directly the activity of
Rac1, Cdc42, and RhoA in cells transfected with our Vav2 constructs. Because of their high transfection efficiency, CHO cells were used for
these experiments. Measuring the amount of GTP bound to Rho family
proteins has been difficult because of high intrinsic GTPase rates and
because antibodies against these proteins are generally not good for
immunoprecipitation. We have employed affinity precipitation assays to
measure the amount of these proteins that have GTP bound (4, 6,
40, 43). To measure the amounts of active Rac1 and Cdc42, we used
a GST construct of PAK3, which selectively binds to the GTP-bound but
not GDP-bound forms of Rac1 and Cdc42 (3, 4). To measure the
level of active RhoA, we used a GST construct of Rhotekin, which
selectively binds to the GTP-bound form of RhoA but not the GDP-bound
form (40). Glutathione-Sepharose beads complexed to the
described GST fusion proteins were used to affinity precipitate
GTP-bound Rac1, Cdc42, or RhoA. The amount of active G protein was
detected by blotting with antibodies to Rac1, Cdc42, and RhoA.
Expression of
184N Vav2 in CHO cells resulted in elevated levels of
active Rac1, Cdc42, and RhoA compared with control cells
expressing GFP
alone (Fig.
7). With RhoA and Rac1, the
level of
increase was about 1.7-fold, whereas with Cdc42, the increase
in several experiments was greater, although more variable (Fig.
7d).
These experiments involved transient transfection of
184N
Vav2, and
only about 30% of the cells on a dish were transfected.
Consequently,
the level of active RhoA and Rac1 in the cells expressing
184N Vav2
would have been elevated approximately 2.5-fold above
the level in
untransfected cells. For Cdc42, the level of activation
would have been
still higher. We also investigated the effect
of transfecting wild-type
Vav2 on Rac1 and RhoA activity and found
that overexpression of Vav2
increased the level of activity of
both of these proteins, but to a
lesser extent than
184N Vav2
(data not shown). All the above
experiments were conducted with
cells grown in the presence of serum.
We were concerned that factors
present in serum, such as
lysophosphatidic acid, would activate
RhoA (
41) and that
greater effects on RhoA activity might be
seen in the absence of serum.
Consequently, we also examined the
effect of
184N Vav2 expression on
RhoA activity in serum-starved
cells. However, this revealed
essentially equivalent levels of
RhoA activation in response to
184N
Vav2 expression in the absence
of serum as in the presence of serum
(data not shown).
View larger version (26K):
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|
FIG. 7.
Vav2 expression elevates the activity of Rac1, Cdc42,
and RhoA in cells. (a to c) Blots with anti-Rac1, Cdc42, and RhoA are
shown, respectively. In each case, the top panels show immunoblots of
the protein that was sedimented by either the GST-PBD beads (i.e.,
Rac1-GTP or Cdc42-GTP) or the GST-RBD beads (i.e., RhoA-GTP) after
incubation with lysates from cells transfected with GFP or 184N
Vav2. The bottom panels show blots of the corresponding cell lysates.
(d) Graphical representation of relative activity of RhoA, Rac1, and
Cdc42 in cells transfected with 184N Vav2. The activity level of
RhoA, Rac1, and Cdc42 in cells transfected with GFP was set at 1. Each
bar represents the mean of three separate experiments (error bars,
standard error of the mean). For the increase in RhoA and Rac activity,
P < 0.001. For the increase in Cdc42 activity,
P = 0.03.
|
|
Previous studies have demonstrated that growth factors such as EGF and
PDGF stimulate Rac activity (
24,
35,
42). We
have shown here
that these growth factors also result in the tyrosine
phosphorylation
of Vav2 (Figure
1b and c), and previously tyrosine
phosphorylation of
Vav2 has been shown to activate it as an exchange
factor
(
46). To determine whether Vav2 was required for growth
factor-mediated activation of Rac1, we expressed the SH3-SH2-SH3
carboxy-terminal construct as a putative dominant negative form
of
Vav2. HEK293 cells were transfected with GFP alone or with
the
SH3-SH2-SH3 Vav2 C-terminal construct. The cells were stimulated
with
EGF for 20 min, and the level of active Rac1 was measured
(Fig.
8). For these experiments, quantitation
was performed by
phosphorimager analysis of the immunoblots.
Stimulation of the
cells with EGF resulted in an approximately 1.8-fold
elevation
in Rac1 activity. Expression of the C-terminal Vav2 construct
consistently reduced the level of EGF-stimulated Rac1 activity
to about
30% of the level achieved by EGF stimulation of cells
expressing GFP
(
P = 0.03). Because only a fraction of the cells
were
transfected with the Vav2 C terminus, these results suggest
that
expression of this Vav2 construct blocked the elevation in
Rac1
activity induced by EGF. This supports the idea that EGF
stimulates a
rise in Rac1 activity, at least in part through activation
of
endogenous Vav2.
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 8.
Expression of the carboxy terminus of Vav2 decreases
EGF-induced Rac1 activation. HEK293 cells were either untreated
( ) or stimulated for 20 min with EGF (100 ng/ml), and the level
of active Rac1 was measured using sedimentation with GST-PBD beads,
blotting for Rac1, and phosphorimager analysis. The level of Rac1
activity in unstimulated cells was set at 100%. Comparison of
EGF-treated cells with unstimulated cells indicated an increase in Rac1
activity of approximately 1.8-fold (P = 0.01).
Expression of the Vav2 C-terminal construct compared with
expression of GFP decreased the level of Rac1 activity in
EGF-stimulated cells by approximately 30% (P = 0.03).
The data were compiled from four separate experiments. Error bars,
standard error of the mean.
|
|
| |
DISCUSSION |
At the outset of this work, we were interested in determining
whether the GEF Vav2 acts downstream of 1 integrin engagement in
nonhematopoietic cells. 1 integrins mediate the adhesion of cells to
many ECM proteins (27). During the process of adhesion and
spreading on ECM substrates, cells extend filopodia and lamellipodia, and over a longer time course they develop stress fibers. These cytoskeletal rearrangements are regulated by Cdc42, Rac1, and RhoA,
respectively, three low-molecular-weight G proteins that belong to the
Ras superfamily (22, 50). The activity of these proteins can
be stimulated by many soluble factors, and recent work has shown that
1 integrin-mediated adhesion itself stimulates rapid activation of
Cdc42 and Rac1 (14, 38) and a slower activation of RhoA
(5, 40). The pathway from 1 integrins to the activation of these Rho family proteins has not been determined, but it is likely
to involve activation of GEFs or inhibition of GAPs.
Previous work has demonstrated a link between multiple integrins and
Vav1, a Rho family GEF restricted to hematopoietic cells. Vav1 becomes
activated in response to tyrosine phosphorylation (16, 23).
Platelet adhesion to fibrinogen via the integrin IIb3, or to
collagen or fibronectin via 1 integrins leads to a rapid tyrosine
phosphorylation of Vav1 (12). Expression of IIb3 and
Vav1 in CHO cells, together with the hematopoietic tyrosine kinase,
Syk, led to activation of Vav1 when these cells adhered to fibrinogen
via the expressed IIb3 (31). In addition, these cells
developed a pronounced Rac1 phenotype of extensive lamellipodia and
ruffling membranes. This work led us to investigate whether the widely
distributed Vav family member Vav2 might function as a GEF downstream
from 1 integrin engagement in nonhematopoietic cells. Vav2 shares
extensive homology with Vav1, including the same domain structure
(9, 45). Tyrosine phosphorylation has been shown to activate
Vav2 as it does Vav1 (46); therefore, we used tyrosine
phosphorylation as an indicator of Vav2 activity. Contrary to our
expectations, we were unable to detect elevated phosphotyrosine in Vav2
in cells plated on fibronectin or collagen, both of which are ligands
for 1 integrins. These results indicated that Vav2 is unlikely to
act as a Rho family GEF downstream of integrins in the fibroblastic and
epithelial cells that we have examined. We began to explore other
agents that might promote Vav2 tyrosine phosphorylation and hence
activation. We found that the growth factors EGF and PDGF resulted in a
rapid but transient tyrosine phosphorylation of this exchange factor.
Similarly, Moores and colleagues have also found that Vav2 is tyrosine
phosphorylated in response to EGF and PDGF, but not tyrosine
phosphorylated in response to integrin-mediated adhesion
(31a). After completion of our work, the association of
tyrosine phosphorylated Vav2 with the EGF and PDGF receptors was
described (37).
We have been interested in the targets of Vav2 activity. Initial
studies measuring GEF activity in vitro indicated that Vav2 differed
from Vav1 with respect to its targets in the Rho family (46). Vav1 has been shown to act on Rac1, Cdc42, and RhoA
(16, 23), whereas Vav2 was noted to act on RhoA and RhoG,
but not on Rac1 or Cdc42 (46). A different result, however,
has been obtained from Abe et al., who have found that Vav2 has
exchange factor activity for Rac1, Cdc42, and RhoA in vitro
(1). To explore the activity of Vav2 in cells, we have
expressed a GFP-tagged construct of wild-type Vav2, as well as a
GFP-tagged, amino-terminally truncated version of the protein.
Amino-terminal truncation of many GEFs renders them constitutively
active and oncogenic (10, 51), and this is also true with
Vav1 and Vav2 (1, 9, 46). We have examined both the actin
cytoskeletal organizations of cells overexpressing these Vav2
constructs and measured the level of active Rac1, Cdc42, and RhoA.
Morphologically, cells expressing Vav2 or its oncogenic, truncated form
revealed both a Rac1 and a RhoA phenotype. The cells displayed
extensive lamellipodia and ruffling membranes but also had prominent
stress fibers. In addition, these cells showed enhanced cell migration.
We found that the increased migration was inhibited by coexpression of
dominant negative forms of Rac1 or Cdc42. These dominant negative
constructs also inhibited the prominent membrane ruffling induced in
cells expressing the constitutively active form of Vav2.
In order to measure the level of active Rac1, Cdc42, and RhoA, we have
used affinity precipitation assays in which only the GTP-bound forms of
these proteins are sedimented by binding to immobilized effector fusion
proteins (4, 6, 40, 43). Expression of these Vav2
constructs, particularly the amino-terminally truncated form, resulted
in elevated levels of Rac1, Cdc42, and RhoA. These results are
consistent with the mixed Rac1 and RhoA phenotypes, i.e., with cells
exhibiting prominent ruffling membranes and also stress fibers. In
general, we did not observe an obvious Cdc42 morphological phenotype,
but the development of filopodia is often obscured by Rac1 activation,
as filopodia become engulfed by lamellipodia and membrane ruffles. Our
results indicate that Vav2 activates Rac1, Cdc42, and RhoA. Although
this appears to differ from the results of Schuebel et al.
(46), who noted Vav2 activating RhoA and RhoG in vitro but
not Rac1 or Cdc42, it should be noted that RhoG has been implicated in
downstream activation of both Rac1 and Cdc42 (19). At
present, we cannot say whether the elevation of Rac1 and Cdc42 activity
in cells overexpressing Vav2 is due to a direct activation of these
proteins by Vav2 or is indirect and mediated by Vav2 acting on RhoG.
The tyrosine phosphorylation of Vav2 in response to stimulating cells
with EGF or PDGF suggests that it contributes to Rac1 activity induced
by these growth factors. Consistent with this possibility, we found
that expression of a carboxy-terminal fragment of Vav2, which is
predicted to compete with Vav2 for interactions mediated via its SH3
and SH2 domains, decreased the level of active Rac1 in cells stimulated
with EGF (Fig. 8). Similarly, in preliminary studies, we have noted
that expression of this C-terminal construct of Vav2 decreases Rac1
activity in cells stimulated with PDGF (data not shown). Previous work,
however, has implicated Sos1 (32) and Sos1 complexed with
Eps8 and E3b1/Abi-1 (48) in the elevation of Rac1-GTP levels
downstream from receptor tyrosine kinases. It seems likely that there
are multiple pathways that lead from receptor tyrosine kinases to Rac1
activation. In future work, it will be important to compare the
relative contributions of these and other GEFs to the activation of Rho
family proteins following cell stimulation by growth factors.
Although our data demonstrate a role for Vav2 in growth factor
signaling to the cytoskeleton, the morphological phenotype of cells
expressing activated Vav2 differs from that of growth factor-stimulated
cells. Cells overexpressing either full-length or activated Vav2
display both extensive membrane ruffles and increased stress fibers,
indicative of a combination of Rac1 and RhoA activation. In contrast,
growth factors, such as EGF and PDGF, rapidly induce membrane ruffling,
but this is accompanied by a loss of stress fibers and focal adhesions
(39, 42, 52). In some situations, this initial induction of
membrane ruffles in response to growth factors is followed by a slower
development of stress fibers (42). It is possible that the
function of Vav2 downstream from growth factor receptors is to mediate
the second phase of actin rearrangements in which both membrane ruffles
and stress fibers coexist. However, the time course of Vav2 tyrosine phosphorylation in response to growth factors is rapid and would be
expected to result in an immediate stimulation of both Rac1 and RhoA
activity. An alternative explanation is that, coincident with the
initial activation of Vav2 by growth factors, a Rho GAP is
simultaneously activated and that this antagonizes RhoA activation. Previous studies have indeed provided evidence for activation of
p190RhoGAP in response to EGF stimulation (11). One
scenario that we can envisage is a biphasic response to growth
factor stimulation, in which transient activation of p190RhoGAP is
coupled with a more sustained activation of Vav2. This would result
first in a decrease in RhoA activity that would be followed by an
increase with time. Such a response may be important in cell migration, a process that is triggered by growth factors like PDGF and EGF. Evidence has been presented that too-strong adhesion, such as that
provided by focal adhesions, can antagonize cell migration (26). The disassembly of stress fibers and focal adhesions
induced by growth factors has been suggested to remove a brake that
would otherwise retard migration. However, recent work has established that, while too much RhoA activity inhibits migration, some RhoA activity is necessary (34). Consequently, the activation of Vav2 by EGF and PDGF may contribute to cell migration not only by
activating Rac1 and Cdc42, but also by activating RhoA.
Vav2 contains many domains involved in binding other components. It
seems likely that its interactions with other components will be
important in regulating its activity in various situations. A goal for
the future will be to identify these interactions and to determine how
these interactions affect Vav2 activity and contribute to regulating
complex events such as cell migration.
| |
ACKNOWLEDGMENTS |
We are most grateful to Joan Brugge and Sheri Moores for sharing
their data with us prior to their publication. David Kwiatkowski kindly
provided us with Vav2 cDNA. Many of our laboratory colleagues have
contributed advice and encouragement. We especially thank Bill Arthur,
Nikki Noren, Leslie Petch, Sarita Sastry, Amy Shaub, and Becky
Worthylake. B.L. thanks Simone Schoenwaelder and Magda Chrzanowska-Wodnicka for sustained encouragement. We thank Michele Alexandre for technical assistance.
This work was supported by NIH grant GM29860.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Cell Biology and Anatomy, 108 Taylor Hall, CB#7090, Chapel Hill, NC
27599-7090. Phone: (919) 966-5783. Fax: (919) 966-1856. E-mail:
bliu{at}med.unc.edu.
| |
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Molecular and Cellular Biology, October 2000, p. 7160-7169, Vol. 20, No. 19
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
