(Received for publication, March 11, 1997, and in revised form, March 28, 1997)
From the Cruciform Project and Department of Medicine, University College London, 5 University Street, London WC1E 6JJ, United Kingdom
Vascular endothelial growth factor (VEGF)
stimulated the tyrosine phosphorylation of multiple components in
confluent human umbilical vein endothelial cells (HUVECs) including
bands of Mr 205,000, corresponding to the VEGF
receptors Flt-1 and KDR, and Mr 145,000, 120,000, 97,000, and 65,000-70,000. VEGF caused a striking and
transient increase in mitogen-activated protein (MAP) kinase activity
and stimulated phospholipase C- tyrosine phosphorylation, but it had
no effect on phosphatidylinositol 3
-kinase activity. VEGF caused a
marked increase in tyrosine phosphorylation of p125 focal adhesion
kinase (p125FAK), which was both rapid and
concentration-dependent. VEGF produced similar effects on
p125FAK in the endothelial cell line ECV.304. VEGF
stimulated tyrosine phosphorylation of the 68-kDa focal
adhesion-associated component, paxillin, with similar kinetics and
concentration dependence to that for p125FAK. Thrombin and
the phorbol ester, phorbol 12-myristate 13-acetate, also increased
p125FAK tyrosine phosphorylation in HUVECs. The effect of
VEGF on p125FAK tyrosine phosphorylation was completely
inhibited by the actin filament-disrupting agent cytochalasin D and was
partially inhibited by the protein kinase C inhibitor GF109203X.
Inhibition of the MAP kinase pathway using a specific inhibitor of MAP
kinase kinase had no effect on p125FAK tyrosine
phosphorylation. VEGF stimulated migration and actin stress fiber
formation in confluent HUVEC, and VEGF-induced
p125FAK/paxillin tyrosine phosphorylation was accompanied
by increased immunofluorescent staining of p125FAK,
paxillin, and phosphotyrosine in focal adhesions in confluent cultures
of HUVECs. These findings identify p125FAK and paxillin as
components in a VEGF-stimulated signaling pathway and suggest a novel
mechanism for VEGF regulation of endothelial cell functions.
The endothelium lining the lumen of all blood vessels plays
essential roles in the development and the function of the vasculature. It is central to angiogenesis, the maintenance of vascular tone and of
vascular permeability, and is also involved in several disease states,
particularly atherosclerosis and other vasculoproliferative disorders
(1-3). A key regulator of endothelial cell functions is the 46-kDa
secreted polypeptide growth factor, VEGF,1
also known as vascular permeability factor (4-6). VEGF, which exists
in at least four isoforms generated by alternative splicing from a
single gene (7), is a major hypoxia-inducible angiogenic factor in
tumors (8-10), and its expression is also up-regulated by hypoxia and
by PDGF-BB, transforming growth factor-, and basic fibroblast growth
factor in arterial VSMC (11-13). In addition to its angiogenic
activity, VEGF increases the permeability of vascular endothelium (14),
stimulates migration of monocytes through endothelial monolayers (15,
16), and acts as a specific mitogen for endothelial cells (17).
Recent findings indicate that VEGF may have diverse effects in the cardiovascular system. Administration of VEGF protein and VEGF gene transfer inhibit intimal thickening following balloon angioplasty and improve blood flow in ischemic limbs, effects mediated through stimulation of endothelial cell regrowth and angiogenesis, respectively (18-20). VEGF is up-regulated in ischemic myocardium (21), and it has been proposed that VEGF may play a role in neovascularization of the advanced atherosclerotic plaque (10, 22, 23).
VEGF exhibits high affinity binding to two distinct protein tyrosine
kinase receptors, the fms-like tyrosine kinase Flt-1 and
KDR, the human homologue of Flk-1. Both receptors possess insert
sequences within their catalytic domains and seven immunoglobulin-like domains in the extracellular regions and are related to the PDGF family
of receptor protein-tyrosine kinases (24-27). Although expression of
both VEGF receptor types occurs in adult endothelial cells including
HUVECs, recent findings suggest that KDR and not Flt-1 is able to
mediate the mitogenic and chemotactic effects of VEGF in endothelial
cells (28, 29). The key targets for either VEGF receptor that mediate
VEGF's diverse biological functions in endothelial cells remain
incompletely understood, and to date studies of the downstream
effectors and targets for the VEGF receptor have yielded varying
results (29-31). Thus, VEGF has been reported to induce tyrosine
phosphorylation of PLC-, of p120GAP, and of the Src homology 2 domain protein Nck in bovine aortic endothelial cells (30), while in
porcine aortic endothelial cells transfected with KDR and Flt-1, VEGF
had no effect on PLC-
tyrosine phosphorylation or PI 3-kinase
activity and only a weak effect on p120GAP tyrosine phosphorylation
(29).
In addition to its mitogenic effects in endothelial cells, VEGF also
promotes the migration of endothelial cells, and it is increasingly
recognized that endothelial cell migration plays an essential role in
angiogenesis and vascular modeling (29, 32, 33). There is increasing
evidence that p125FAK (34-36), a member of a growing
family of nonreceptor protein-tyrosine kinases (37, 38), may play a key
role in regulating the dynamic changes in actin cytoskeleton
organization that are a prerequisite for cell migration (35, 36).
p125FAK is associated in fibroblastic cells with focal
adhesions, specialized subcellular structures that play a crucial role
in mediating cell adhesion and motility, and its tyrosine
phosphorylation is stimulated by 1 and
3
integrins (39-41) and by a variety of regulatory peptides and lipids
that act through G-protein-coupled receptors (42-44). It has recently
been demonstrated that p125FAK tyrosine phosphorylation is
regulated by growth factor ligands for receptor protein-tyrosine
kinases, including PDGF-BB, a potent chemoattractant for vascular
smooth muscle cells (45-47). P125FAK tyrosine
phosphorylation is also stimulated by other chemoattractants including
hyaluronan and the T-lymphocyte chemokine, RANTES (regulated on
activation normal T cell-expressed) (48, 49). Tyrosine phosphorylation
of p125FAK is associated in several cell types with that of
paxillin, a 68-kDa protein that co-localizes to focal adhesions (45,
49-52). Paxillin has been reported to associate with
p125FAK and is a putative substrate for p125FAK
(53, 54). Further evidence for the role of p125FAK in cell
migration has come from studies in knockout mice and from
overexpression. Murine p125FAK knockout embryos displayed
disorganized mesenchymal tissue architecture, and embryonic mesodermal
fibroblasts deficient in p125FAK exhibited a decreased rate
of cell movement compared with wild-type cells (55). Overexpression of
p125FAK in Chinese hamster ovary cells was found to be
associated with increased cell migration (56).
The role of p125FAK in endothelial cell signal transduction pathways stimulated by VEGF is unknown. In the present paper, we investigated the tyrosine phosphorylation events stimulated by VEGF in human endothelial cells including p125FAK and paxillin tyrosine phosphorylation. We report here that tyrosine phosphorylation of p125FAK and paxillin are rapid events in the signal transduction pathways stimulated by VEGF, which may play a role in the migratory cell response to this factor.
HUVECs were obtained from Clonetics and were routinely cultured in the manufacturer's own medium supplemented with 2% fetal bovine serum. For experimental purposes, primary cultures of HUVECs were dispersed by treatment with 0.05% trypsin, 0.02% EDTA for 5 min at 37 °C and then replated in either 90- or 35-mm plastic dishes. Cultures were maintained in a humidified atmosphere containing 5% C02 and 90% air at 37 °C. For experimental purposes, cells were plated either in 33-mm Nunc Petri dishes at 105 cells/dish, or in 90-mm dishes at 2.5 × 105 cells/dish and used after 6-8 days or when the cells had formed a confluent monolayer. In some experiments, cells were rendered quiescent by incubation with M199 medium containing 1% FCS and without other supplements for 24 h. The human endothelial cell line ECV.304 (57) was maintained and propagated in M199 medium supplemented with 10% FCS. For some experiments, aortic medial VSMC were cultured from rabbit aortas by the tissue explant method as described (46). VSMC were grown to confluence in DMEM containing 20% FCS and were rendered quiescent by incubation for 40 h in DMEM containing 0.5% FCS.
Assays of Cell MigrationCell migration was measured in a modified Boyden chemotaxis chamber (NeuroProbe Inc., Cabin John, MD) essentially as described (46). Test chemoattractants were diluted in DMEM supplemented with 1% (w/v) bovine serum albumin (Sigma) and placed in the bottom wells of the chamber. Polycarbonate filters with 8-µm pores (Polyfiltronics) were preincubated in a 0.1% solution of collagen type I (Sigma) and placed between the chemoattractants and the upper chambers. Cells were trypsinized and washed twice in M199 and resuspended in M199 containing 1% (w/v) bovine serum albumin to give a final cell concentration of 3 × 105/ml. 15,000 cells were placed into each well in the upper chamber, and the chemotaxis chambers were routinely incubated at 37 °C for 6 h. After the incubation, unmigrated cells were removed from the upper side of the filters, and migrated cells were stained with Pro-Diff (Braidwood Laboratories, Beckenham, Kent, UK). Filters were mounted onto microscope slides, and stained cells were counted at × 200 magnification in four fields/well. In each individual experiment, chemotaxis was performed in four separate wells for each concentration of a given test substance under a specified condition. Each n value in the figure legends refers to the number of individual experiments.
ImmunoprecipitationsQuiescent cultures of cells (approximately 106/immunoprecipitation) were washed twice with M199 medium, treated with peptide factors in 1 ml of this medium as indicated, and lysed at 4 °C in 1 ml of a solution containing 10 mM Tris/HCl, pH 7.6, 5 mM EDTA, 50 mM NaCl, 30 mM sodium pyrophosphate, 50 mM NaF, 0.1 mM Na3VO4, 1 mM phenylmethylsulfonyl fluoride, 0.5% Nonidet P-40, and 1% Triton X-100 (lysis buffer). Lysates were clarified by centrifugation at 15,000 × g for 10 min and precleared by incubation with albumin-agarose for 1 h at 4 °C. After removal of albumin-agarose by brief (10-s) centrifugation, the supernatants were transferred to fresh tubes for immunoprecipitation. Immunoprecipitations were routinely performed by incubating lysates with 1 µg/ml antibody as indicated for 3 h at 4 °C. Immunocomplexes were collected either by incubating lysates with protein A-agarose beads for a further 1 h or by incubating with 5 µg/lysate anti-mouse IgG for 1 h followed by a 1-h incubation with protein A-agarose beads. Immunoprecipitates were washed three times with lysis buffer, and proteins were extracted with 2 × SDS-PAGE sample buffer. Phosphotyrosyl proteins were immunoprecipitated with the anti-Tyr(P) mAb Py20. Immunoprecipitates were washed three times with lysis buffer and further analyzed by Western blotting.
Western BlottingTreatments of quiescent cultures of cells with factors, cell lysis, and immunoprecipitations were performed as described above. After SDS-PAGE, proteins were transferred to Immobilon membranes (Millipore Corp.). Membranes were blocked using 5% nonfat dried milk in phosphate-buffered saline, pH 7.2, and incubated for 3-5 h in phosphate-buffered saline, 0.05% Tween-20 containing either anti-Tyr(P) or protein-specific antibodies (1 µg/ml of each) as indicated. Immunoreactive bands were visualized either by chemiluminescence using horseradish peroxidase-conjugated anti-mouse or anti-rabbit IgG and ECLTM reagent or using 125I-labeled sheep anti-mouse IgG or protein A as indicated.
Assays of PI 3-Kinase ActivityPI 3-kinase was determined
by measuring phosphatidylinositol phosphorylation in
anti-phosphotyrosine immunoprecipitates as described (58, 59).
Immunoprecipitates were washed three times with lysis buffer, once in
50 mM Hepes, pH 7.5, and once in PI 3-kinase assay buffer
(20 mM Tris/HCl, pH 7.5, 100 mM NaCl, 0.5 mM EDTA). Immunoprecipitates were preincubated in 25 µl
of PI 3-kinase assay buffer and 10 µl of phosphatidylinositol for 20 min at 4 °C. In some experiments, inhibitors of PI 3-kinase were also added to immunoprecipitates for this preincubation period. Reactions were initiated by the addition of 15 µl of assay mixture containing 10 µCi of [-32P]ATP, 100 µM
ATP, and 10 mM MgCl2, and incubations were
routinely performed for 10 min at room temperature. Reactions were
terminated by the addition of 100 µl of 1 N HCl followed
by the addition of 200 µl of a 1:1 mix of CHCl3 and
methanol. Samples were vortexed for 20 s, and the phases were
separated by centrifugation at 15,000 × g for 2 min.
The lower CHCl3 phase was collected and washed with 80 µl
of a 1:1 mix of 1 N HCl and methanol, and the phases were
separated by centrifugation as before. The lower phase was collected
and applied to LK6D6 silica gel TLC plates (Whatman), which had been
presprayed with 1% potassium oxalate and allowed to dry prior to
sample application. TLC plates were routinely developed for 45 min
using a 29.2:180:10.8:140 mixture of H2O, CHCl3, NH4OH, and methanol, respectively.
Developed TLC plates were dried and exposed to x-ray film for 1-3
days.
Cells were treated with factors as indicated, washed rapidly twice with ice-cold PBS, and immediately extracted by the addition of 100 µl of boiling 2 × SDS-PAGE sample buffer. Cell extracts were collected by scraping, heated to 95 °C for 10 min, and run on 12.5% acrylamide SDS-PAGE gels. Following transfer to Immobilon membranes, proteins were immunoblotted with an antibody that specifically recognizes p42 and p44 MAP kinases (extracellular signal-regulated kinases 1 and 2) activated by phosphorylation at Tyr204 (60).
Immunofluorescent StainingHUVECs were cultured on glass coverslips and allowed to grow to confluence. Following treatments, cells were washed three times with ice-cold PBS and then fixed in 3% paraformaldehyde in PBS for 30 min at 4 °C. Cells were permeabilized with 0.2% Triton X-100 in PBS for 10 min at room temperature and then washed three times in PBS. Fixed and permeabilized cells were incubated with primary antibody for 1 h at room temperature, washed three times in PBS, and then incubated for 45 min at room temperature with a secondary antibody conjugated to FITC. Cells were finally washed three times (5 min each wash) in PBS. Coverslips were mounted onto microscope slides using Vectashield mounting medium. Filamentous actin was stained with FITC-phalloidin in PBS (1 µg/ml) for 20 min at room temperature. Immunofluorescent staining was observed and photographed using a Zeiss Axiophot epifluorescence microscope fitted with a × 63 (numerical aperture 1.4, oil) objective lens.
MaterialsRecombinant VEGF was obtained either from Upstate
Biotechnology, Inc. or from R & D Systems. Cytochalasin D was from
Sigma. Wortmannin was obtained either from Cambridge Bioscience or from Sigma, and PD98059 was obtained from Calbiochem. The BC3 polyclonal antibody to p125FAK was a gift of Professor Thomas Parsons
(University of Virginia). Py20 anti-Tyr(P) mAb and mAbs to
p125FAK, paxillin, Pyk2, p85, and PLC-
were from
Transduction Laboratories, Inc. 4G10 anti-Tyr(P) mAb was from TCS
biologicals Ltd. Antibody to the activated phosphorylated form of
p42/p44 MAP kinase was purchased from New England Biolabs Inc. The U13
antibody to p85
was a gift of Mike Waterfield (Ludwig Institute of
Cancer Research, London). PDGF-BB, Protein A-agarose, goat anti-rabbit
IgG, and goat anti-mouse IgG were from Oncogene Science, Inc.
ECLTM reagents and horseradish peroxidase-conjugated
anti-mouse IgG were from Amersham, UK. All other reagents used were of
the purest grade available.
Treatment of cultured HUVECs stimulated the tyrosine
phosphorylation of multiple protein bands as detected by anti-Tyr(P) blots of anti-Tyr(P) immunoprecipitation. The major bands
phosphorylated were of Mr 205,000, 185,000, 145,000, 125,000, 100,000, and 68,000 (Fig. 1). The
predicted molecular mass of both KDR and Flt-1 VEGF receptors is
approximately 150 kDa, but due to glycosylation of the extracellular
domain, these proteins characteristically migrate in SDS-PAGE gels as
bands of Mr 205,000. The effects of VEGF on PI
3-kinase activity, MAP kinase activation, and PLC- tyrosine phosphorylation were subsequently investigated. VEGF induced neither tyrosine phosphorylation of the p85
PI 3-kinase subunit as judged by
immunoblot of anti-Tyr(P) immunoprecipitates with a specific p85
mAb
(results not shown) nor an increase in PI 3-kinase activity measured in
parallel anti-Tyr(P) immunoprecipitates (Fig.
2A). VEGF also failed to increase PI 3-kinase
activity measured in immunoprecipitates prepared with a specific
anti-p85
antibody (results not shown). It was verified in parallel
assays that PDGF-BB induced PI 3-kinase activity in VSMC as measured
either in anti-Tyr(P) or anti-p85
immunoprecipitates (Fig.
2A and results not shown). We also examined whether VEGF
activated the MAP kinase cascade, a convergent pathway in the action of
many growth factors. Western blotting of HUVEC extracts with an
antibody specific for the activated tyrosine-phosphorylated form of MAP
kinase showed that a 10-min treatment with VEGF caused a striking
activation of MAP kinase, which declined to near the control
unstimulated level after 60 min (Fig. 2B, top).
VEGF increased activity of both p42 and p44 forms of MAP kinase
corresponding to extracellular signal-regulated kinases 1 and 2, respectively, although it was consistently noted that activation of p42
MAP kinase was more prominent than that of the p44 form. VEGF
stimulation of MAP kinase was completely inhibited by the specific MAP
kinase kinase inhibitor PD98059 (61, 62), indicating that activation of
MAP kinases by VEGF occurs through the kinase cascade that mediates
activation of MAP kinase by other growth factors (Fig. 2B,
bottom). VEGF also stimulated tyrosine phosphorylation of
PLC-
. Western blotting of anti-Tyr(P) immunoprecipitates with a
specific PLC-
mAb revealed a striking increase in a major 145-kDa
band in HUVECs treated with 10 ng/ml VEGF for 10 min (Fig.
2C).
The results shown in Figs. 1 and 2 showed that VEGF stimulated the
tyrosine phosphorylation of multiple protein bands, activated p42/p44
MAP kinases, stimulated PLC- tyrosine phosphorylation and failed to
activate PI 3-kinase. It was next investigated whether the 125-kDa band
tyrosine-phosphorylated in response to VEGF corresponded to
p125FAK. Confluent cultures of HUVECs were treated with 10 ng/ml VEGF for different times, and anti-Tyr(P) immunoprecipitates were
prepared and blotted with a specific p125FAK mAb. As shown
in Fig. 3, VEGF markedly increased p125FAK
tyrosine phosphorylation. The effect of VEGF was rapid with a detectable increase as early as 1 min (Fig. 3A). Although
the effect of VEGF was sustained at times of incubation up to 60 min, it was noted in some experiments that p125FAK tyrosine
phosphorylation declined after 30 min. In other experiments, however
(Fig. 3A, bottom), VEGF-induced
p125FAK tyrosine phosphorylation did not decline at times
up to 1 h after the addition of VEGF. Scanning of five independent
experiments (shown in Fig. 4A) showed that
the half-maximum effect occurred after 1 min and the maximum increase
was at 10 min and that p125FAK tyrosine phosphorylation
declined to approximately half the maximum level of phosphorylation
after 2 h. The maximum mean increase in p125FAK
tyrosine phosphorylation stimulated by VEGF after 10 min was 5-fold
(n = 5) above control unstimulated levels (Fig.
4A).
The effect of VEGF on p125FAK tyrosine phosphorylation was
also potent and concentration-dependent with a detectable
increase as low as 0.5 ng/ml (Fig. 3B). In six independent
experiments, the maximum increase in p125FAK tyrosine
phosphorylation was induced by 10 ng/ml VEGF, and a half-maximum
increase was obtained at a concentration of 2.5 ng/ml (Fig.
4B). At concentrations of VEGF above 10 ng/ml,
p125FAK tyrosine phosphorylation partially declined (Figs.
3B and 4B) but remained significantly above
unstimulated levels at the highest concentration tested (25 ng/ml). As
shown in Fig. 3C, VEGF also induced a
concentration-dependent increase in p125FAK
tyrosine phosphorylation in confluent cultures of the human endothelial cell line ECV.304. It was tested whether tyrosine phosphorylation of
the major 125-kDa phosphotyrosyl band seen in anti-Tyr(P) blots of
anti-Tyr(P) immunoprecipitates (Fig. 1) could be accounted for by
Pyk2/CAK, a recently identified p125FAK-related
protein-tyrosine kinase (37, 38). VEGF did not stimulate tyrosine
phosphorylation of Pyk2 as judged by immunoblotting of anti-Tyr(P)
immunoprecipitates with specific Pyk2 antibody (results not shown).
To examine whether the 68-kDa focal adhesion-associated protein
paxillin was also tyrosine-phosphorylated in HUVECs in response to
VEGF, anti-Tyr(P) immunoprecipitates prepared from VEGF-treated cells
were immunoblotted with a specific anti-paxillin antibody. Fig.
5 shows that VEGF increased paxillin tyrosine
phosphorylation in HUVECs with a concentration dependence and kinetics
similar to that obtained for p125FAK. Compared with
p125FAK, paxillin tyrosine phosphorylation exhibited a more
marked decline at higher concentrations (above 10 ng/ml) of VEGF.
Scanning densitometry showed, however, that VEGF-stimulated paxillin
phosphotyrosine content remained above the basal level even at the
highest VEGF concentration (25 ng/ml) tested. The effect of 10 ng/ml
VEGF on paxillin tyrosine phosphorylation was also rapid with a
detectable increase as early as early as 1 min after the addition of
VEGF, reached a maximum by 30 min, and was sustained for up to 60 min after the addition of VEGF. In three independent experiments the maximum mean increase in paxillin tyrosine phosphorylation was 5-fold
above control levels.
The effects on p125FAK tyrosine phosphorylation of other
factors in HUVECs was also investigated. Thrombin, like VEGF, increases endothelial permeability (63, 64), and p125FAK tyrosine
phosphorylation is increased in thrombin-activated platelets (65, 66)
and in thrombin-treated mesangial cells (67). Thrombin treatment of
confluent HUVECs produced an increase in p125FAK tyrosine
phosphorylation in HUVECs comparable with the effect of VEGF (Fig.
6A). Since VEGF has been reported to activate
phospholipase C- it was also examined whether the
p125FAK tyrosine phosphorylation pathway could be
stimulated by agents that directly activate the signaling events distal
to phospholipase C-
activation. As shown in Fig. 6A,
treatment with the biologically active phorbol ester, phorbol
12-myristate 13-acetate, which directly activates PKC, caused a weak
stimulation of p125FAK tyrosine phosphorylation compared
with the effects of either VEGF or thrombin. A similarly weak effect
was obtained with the Ca2+ ionophore A23187 (Fig.
6A).
The role of the PKC pathway in mediating VEGF-induced p125FAK tyrosine phosphorylation was further examined using the selective PKC inhibitor, GF109203X. HUVECs were pretreated with the PKC inhibitor GF109203X at a concentration (3 µM) that completely blocks PKC activation in several cell types including Swiss 3T3 cells (43, 68). As shown in Fig. 6B, GF209103X caused a partial reduction in VEGF-stimulated p125FAK tyrosine phosphorylation (Fig. 6B). Semiquantification by scanning densitometry showed that in three independent experiments the mean reduction in VEGF-stimulated p125FAK tyrosine phosphorylation consequent upon pretreatment with GF109203X was approximately 40% (n = 3). In accord with findings in other cell types (43, 46, 65), it was verified in parallel cultures that disruption of the actin filament network in HUVECs by a 1-h pretreatment with 2 µM cytochalasin D completely inhibited VEGF stimulation of p125FAK tyrosine phosphorylation (Fig. 6B). It was also examined whether inhibition of the MAP kinase cascade using the specific MAP kinase kinase inhibitor, PD98059, had any effect on p125FAK tyrosine phosphorylation. The results showed that inhibition of MAP kinase activation by pretreatment for 1 h with 10 µM PD98059 had no inhibitory effect on VEGF stimulation of p125FAK tyrosine phosphorylation (Fig. 6B).
VEGF stimulated the directed migration of HUVECs with a half-maximal
effect at approximately 2.5 ng/ml and a maximum effect at 10 ng/ml
(Fig. 7A). Since p125FAK has been
implicated in the regulation of actin cytoskeleton organization, we
tested whether VEGF induced changes in the actin filament network. Staining of confluent cultures of HUVECs with FITC-phalloidin showed
that in control unstimulated cells filamentous actin was characteristically organized in cortical arrays (Fig. 7B).
VEGF treatment stimulated an increase in actin filament formation and in particular increased the number of transverse filament bundles that
crossed the cell. (Fig. 7C).
We subsequently examined whether VEGF-induced signaling through the
p125FAK pathway was concomitant with changes in the
association of p125FAK and paxillin with the actin cytoskeleton. First,
we examined whether VEGF changed the distribution of
p125FAK and paxillin between Triton-soluble and
Triton-insoluble compartments in HUVECs. Indeed, one plausible
explanation for the results presented in Figs. 3, 4, 5, 6 was that the
VEGF-induced increases in p125FAK and paxillin
immunoreactivity recovered by anti-Tyr(P) immunoprecipitation (and/or
the observed decline in p125FAK tyrosine phosphorylation at
higher VEGF concentrations and longer times of treatment) were due to
VEGF-induced changes in the susceptibility of p125FAK and
paxillin to extraction by 1% Triton X-100. This was tested by
performing direct Western blot analysis of 1% Triton X-100 lysates
with antibody to p125FAK and paxillin without prior
immunoprecipitation. As shown in Fig. 8
(top), the conditions under which lysates were normally
prepared for immunoprecipitation resulted in the extraction of
virtually the entire pool of cellular immunoreactive
p125FAK. VEGF treatment for various times up to 60 min had
no significant effect on the extraction of p125FAK as
judged using either an anti-FAK mAb directed against a portion of it
comprising residues 354-533 (Fig. 8) or the BC3 polyclonal anti-FAK
antibody, which specifically recognizes the carboxyl-terminal noncatalytic region of FAK (results not shown). Very similar results were obtained for paxillin (Fig. 8, bottom). In contrast,
the Triton-insoluble fraction contained very little or no
immunoreactive p125FAK and paxillin. It was, however,
consistently noted that the Triton-insoluble fraction contained a major
p125FAK-immunoreactive band of approximate
Mr 55,000, which was either absent or much more
weakly recognized in the Triton-soluble fraction. The 55-kDa band was
seen in Triton-insoluble extracts most strongly by the anti-FAK mAb
directed against amino acid residues 354-533 (Fig. 8, top),
very weakly by BC3, and was also recognized by an antibody that
specifically recognizes the amino terminus of p125FAK
(results not shown). No paxillin-immunoreactive species were found in
the Triton-insoluble fraction.
To further examine the functional significance of VEGF-stimulated
p125FAK tyrosine phosphorylation, the localization of
p125FAK in HUVECs was examined by immunofluorescent
staining. In control, unstimulated cells (Fig.
9A), p125FAK immunostaining was
predominantly diffuse with weak cytoplasmic staining and some staining
putatively of the nuclear or juxtanuclear region.
Anti-p125FAK staining of focal adhesions, which appear as
characteristically elongated dashes or short streaks, was generally
weak in unstimulated cells, and p125FAK-immunoreactive
focal adhesions were relatively sparse and poorly defined. In contrast,
treatment of HUVECs for 30 min with 10 ng/ml VEGF caused a striking
increase in anti-p125FAK immunostaining of focal adhesions
and a large increase in the number of focal adhesions per cell (Fig.
9B). The increase in p125FAK immunostaining of
focal adhesions was also evident after treatment with VEGF for 10 min
(results not shown) and was sustained after 1 h (Fig.
9C) and for up to 4 h (results not shown). VEGF-induced p125FAK immunostaining occurred both at the cell edges,
where, frequently, clusters of short streaks of staining were aligned
in parallel, and in the cell interior. It was noteworthy that
p125FAK staining in the putative nuclear region
consistently exhibited a discrete granular or dotty configuration
characteristically interspersed with areas in which staining was
absent. It was verified that incubation with the FITC-conjugated
secondary antibody alone produced no staining above background.
VEGF also caused a less marked increase in paxillin immunofluorescent
staining of focal adhesions in HUVECs (Fig. 10,
A and B). Control cells exhibited strong diffuse
paxillin immunofluorescent staining in the putative perinuclear region,
and strongly stained focal adhesion-like structures were apparent but
relatively few in number (Fig. 10A). Similar to the results
obtained with p125FAK, VEGF treatment stimulated a
noticeable increase in paxillin staining of focal adhesions (Fig.
10B). Paxillin mAb immunostaining was present both in focal
adhesions and in filamentous arrays aligned in parallel both at the
cell periphery and in the cell interior. A VEGF-induced increase in
paxillin immunostaining of focal adhesions was evident as early as 10 min after the addition of VEGF and was sustained for up to 4 h
(the longest time examined). VEGF also induced some increase in
immunofluorescent staining of vinculin in focal adhesions, although the
increase was less marked than that of p125FAK.
Immunolocalization of vinculin also showed considerable staining of
intercellular junctions in confluent cultures of HUVECs, consistent with the association of vinculin with the endothelial adherens junction
(69) (results not shown).
VEGF-induced changes in p125FAK and paxillin immunofluorescent staining of focal adhesions in HUVECs were paralleled by similar changes in tyrosine phosphorylation in focal adhesions as determined by immunofluorescent staining with the 4G10 anti-Tyr(P) mAb. Control untreated cells exhibited weak focal adhesion and filamentous staining (Fig. 10C). VEGF induced a marked increase in the immunofluorescent staining of focal adhesions and filaments and an increase in the number of immunostained structures (Fig. 10D). The overall pattern of anti-Tyr(P) immunostaining of cytoskeletal structures was very similar in appearance to that observed with p125FAK and paxillin antibodies. A VEGF-induced increase in 4G10 anti-Tyr(P) immunostaining of focal adhesions and actin filaments was also evident after 10 min (results not shown), and similar results were obtained with a different anti-Tyr(P) mAb, Py20 (results not shown).
The results presented here show that in cultures of HUVECs, VEGF induced a striking increase in the tyrosine phosphorylation of the focal adhesion-associated proteins p125FAK and paxillin. The effect of VEGF was both rapid and concentration-dependent. The concentration dependence for VEGF-induced p125FAK/paxillin tyrosine phosphorylation is similar to that observed for the effects of VEGF on mitogenesis in endothelial cells (29) and in the present paper also correlated with the concentration dependence for the chemotactic response of HUVECs to VEGF. Since HUVECs are known to express both KDR and Flt-1 receptors, it is unclear at present which of these receptors is responsible for mediating VEGF activation of the p125FAK/paxillin pathway.
The tyrosine phosphorylation of p125FAK and paxillin was noticeably biphasic with respect to both time of treatment with VEGF and to VEGF concentration. It is plausible that the decline in p125FAK tyrosine phosphorylation could result from disruption of the actin cytoskeleton at higher VEGF concentrations. In this context it is noteworthy that VEGF has been reported to induce disorganization of actin stress fibers in Balb/c 3T3 cells (70). For several reasons, however, our results argue against this interpretation. First, the finding that VEGF stimulation of p125FAK tyrosine phosphorylation was completely abolished by the actin-depolymerizing agent cytochalasin D indicates that, in accord with previous findings in other cell types, activation of the p125FAK pathway in HUVECs by VEGF is critically dependent on the integrity of the actin filament network. Second, VEGF-stimulated p125FAK tyrosine phosphorylation and focal adhesion-associated p125FAK and paxillin immunofluorescent staining remained above control, unstimulated levels at all of the VEGF concentrations examined and for prolonged times of treatment. Third, VEGF at high concentrations did not cause any noticeable perturbations in HUVEC actin filament organization (results not shown). We therefore conclude that the decline in p125FAK/paxillin tyrosine phosphorylation at higher VEGF concentrations, particularly noticeable in the case of paxillin, is unlikely to be related to any disruptive effect of VEGF on the actin cytoskeleton similar to the effects of high concentrations of PDGF in Swiss 3T3 cells (45). Alternatively, the decline in tyrosine phosphorylation after longer times of treatment and at higher concentrations may be related to internalization and down-regulation of VEGF receptors (71). Consistent with this possibility, tyrosine phosphorylation of the 205-kDa band corresponding to the VEGF receptor also exhibited a decline at longer times of treatment.
The major site of tyrosine phosphorylation of p125FAK is
Tyr397. Tyr397 is both a site of
autophosphorylation and is required for association of
p125FAK with the Src homology 2 domains of both Src family
kinases and of the p85 subunit of PI 3-kinase (72, 73).
Phosphorylation of Tyr925 is induced by cell attachment to
fibronectin and is a binding site for the adaptor protein Grb-2 (74).
p125FAK can also be tyrosine-phosphorylated by Src family
kinases at amino acids Tyr407, Tyr576, and
Tyr577, and in addition to Tyr397,
Tyr576, and Tyr577 may also be necessary for
maximum enzymatic activity (75). The putative substrates and sites for
p125FAK-catalyzed tyrosine phosphorylation are still poorly
understood, but a specific residue in paxillin, Tyr118, is
phosphorylated by p125FAK in vitro (76). Since
Tyr118 is located in one of the consensus binding sites in
paxillin for the adaptor protein Crk (77), it is possible that
phosphorylation at this site may serve to modulate association of
paxillin with Crk. Identification of the sites of p125FAK
and paxillin phosphorylation induced by VEGF is likely to be valuable
in elucidating the effects of VEGF on associations between p125FAK/paxillin and other signaling molecules.
The mechanism(s) that mediated VEGF stimulation of the
p125FAK pathway were also investigated. PI 3-kinase has
recently been implicated in the regulation of p125FAK.
Studies with mutant receptors have shown a requirement for the PI
3-kinase binding motif in PDGF-induced cell migration and membrane ruffling (78-80). Furthermore, p125FAK can associate with
both the Src homology 2 and 3 domains of p85 (66, 73) and it was
recently reported that stimulation of p125FAK tyrosine
phosphorylation by PDGF in Swiss 3T3 cells requires PI 3-kinase (81).
The Flt-1 VEGF receptor has been shown to interact in a yeast
two-hybrid system with p85
via a specific residue in the Flt-1
cytoplasmic domain, Tyr1213 (82), but to date, however,
there is no direct evidence that either KDR or Flt-1 can associate with
p85
in vivo. The results presented here show that VEGF
neither stimulates PI 3-kinase nor p85
tyrosine phosphorylation in
HUVECs, thus arguing against the involvement of this pathway in VEGF
stimulation of p125FAK/paxillin tyrosine phosphorylation.
It is not precluded that VEGF may be acting through a distinct PI
3-kinase pathway possibly independent of p85
tyrosine
phosphorylation, which we were unable to detect using available
reagents. The role of VEGF stimulation of the MAP kinase cascade was
also investigated. Recent reports showing that integrin engagement
leads to activation of MAP kinases (83, 84) raise the possibility that
this pathway may mediate stimulation of p125FAK tyrosine
phosphorylation. The finding that a specific inhibitor of this pathway
had no effect on VEGF-induced p125FAK tyrosine
phosphorylation suggests that VEGF activates the p125FAK
pathway independently of MAP kinase activation. This finding is
consistent with the report that integrin-mediated activation of MAP
kinase is dependent on Ras activation and can be dissociated from
adhesion-dependent activation of p125FAK, cell
spreading and focal adhesion, and stress fiber formation (85). We
conclude that VEGF regulation of the p125FAK pathway can be dissociated
from activation of both PI 3-kinase and MAP kinase. The fact that VEGF
has been reported to stimulate PLC-
implicated PKC activation as a
possible mediator of VEGF stimulation of the p125FAK
pathway in HUVECs. Previous findings show that bombesin stimulation of
p125FAK/paxillin tyrosine phosphorylation in Swiss 3T3
cells cannot be accounted for by either the mobilization of
Ca2+ or PKC (43). The findings presented here show that
direct activation of PKC by the biologically active phorbol ester
phorbol 12-myristate 13-acetate had a weak effect on
p125FAK tyrosine phosphorylation relative to those of
either VEGF or thrombin, and a selective PKC inhibitor only partially
inhibited VEGF-stimulated p125FAK tyrosine phosphorylation.
These results suggest that while PKC may partially contribute to VEGF
stimulation of the p125FAK pathway, it is likely that other
signaling pathways are involved. Identification of the relevant signal
transduction events involved warrants further investigation.
Stimulation of the p125FAK/paxillin pathway in HUVECs was accompanied by a marked VEGF-induced increase in the localization of both p125FAK and paxillin to focal adhesions and filamentous structures. It is most likely that the filamentous immunofluorescent staining produced by p125FAK, paxillin, and anti-phosphotyrosine antibodies is due to decoration of actin filaments. The fact that VEGF treatment also stimulated an increase in tyrosine phosphorylation in focal adhesions is consistent with the notion that an increase in p125FAK/paxillin tyrosine phosphorylation occurs concomitantly and is possibly a prerequisite for VEGF-induced localization of these components to focal adhesions. Increased immunofluorescent staining of focal adhesions could reflect either de novo formation of focal adhesions and/or VEGF-stimulated recruitment of p125FAK and paxillin to nascent focal adhesions. The fact that formation of focal adhesions has been shown to occur concomitantly with stress fiber formation (35, 36) and that VEGF also increased stress fiber formation in HUVECs tends to support the former possibility, namely that immunolocalization of p125FAK/paxillin in focal adhesions reflects assembly of focal adhesions. It should be emphasized, however, that previous studies have been performed largely in immortalized Swiss 3T3 cells, and results obtained in these cells may not be readily applicable to primary cultures of other cell types. Immunofluorescent staining of the focal adhesion component, vinculin, showed some increase in response to VEGF, but this appeared to be less marked than that of p125FAK, suggesting that some components in HUVECs may remain constitutively associated in nascent focal adhesions. Furthermore, the presence of considerable diffuse cytoplasmic staining of p125FAK and paxillin, as well as some more discrete staining possibly of the nuclear and perinuclear regions, suggests the existence of substantial non-cytoskeletal-associated pools of these molecules, which could provide a source for recruitment. While focal adhesion formation remains the most likely explanation for increased immunofluorescent localization of p125FAK to these structures, we do not rule out the possibility that active recruitment of p125FAK (and possibly other components) to nascent focal adhesions may also occur. VEGF-induced immunolocalization of p125FAK and paxillin to focal adhesions was not accompanied by an apparent translocation of these components to the Triton-insoluble fraction of VEGF-stimulated HUVECs. This contrasts with a previous report that p125FAK becomes translocated to the actin cytoskeleton in thrombin-stimulated platelets (66), possibly reflecting differences either in the way that p125FAK associates with the actin cytoskeleton or in the manner that VEGF in HUVECs and thrombin in platelets affect the interaction of p125FAK with the actin cytoskeleton.
It was noteworthy that the Triton-insoluble HUVEC fraction was enriched in a 55-kDa p125FAK-immunoreactive species, which was poorly detected in the Triton-soluble fraction. Several variant species of FAK have been reported, including a widely expressed p41/p43FRNK and a species truncated at the amino terminus (86, 87). Since the antibody used for detection of this fragment is directed to a region of the p125FAK molecule comprising amino acid residues 354-533, it is unlikely that the 55-kDa species represents a larger version of p41/p43FRNK that comprises only the noncatalytic carboxyl-terminal domain (86). It is also unlikely that p55 is simply a product of proteolytic breakdown, since extractions were performed in the presence of protease inhibitors and p55 was more weakly detected in the Triton-soluble fraction that contained almost all of the immunoreactive parent 125-kDa species. Determination of whether p55 represents a novel variant of p125FAK or is nonspecifically recognized by antibodies to p125FAK will require further experimental work.
The signaling pathways through which VEGF elicits its diverse
biological effects in target cells have remained elusive. VEGF has
previously been reported to stimulate the directed migration of
endothelial cells (29), but the mechanisms involved have not previously
been investigated. The findings that VEGF stimulated p125FAK and paxillin tyrosine phosphorylation and promoted
their recruitment to focal adhesions are consistent with a role for
these components in VEGF stimulation of endothelial cell migration. It
is likely that the stimulation of endothelial cell motility,
particularly in vivo, involves a more extensive network of
signaling events distal to p125FAK. Tyrosine
phosphorylation of components of the epithelial and endothelial cells
adherens junction, including cadherins and catenins, is associated with
loss of integrity of intercellular adhesions and increased cell
motility (87-89). Although we found no evidence for localization of
p125FAK and paxillin to intercellular junctions, since
components of focal adhesions and of the endothelial adherens junctions
are both linked to the actin cytoskeleton, it is attractive to
speculate that tyrosine phosphorylation of components of focal
adhesions and of adherens junctions may be functionally integrated
through a common program of signaling events in the migration of
endothelial cells. Consistent with this possibility, we found that VEGF
induces tyrosine phosphorylation of the vascular endothelium-specific cadherin-5 and of -catenin in HUVECs.2
Further experimental work is necessary to fully delineate the pathways
and components mediating the regulation of the actin cytoskeleton
network by VEGF.
VEGF regulation of the p125FAK/paxillin pathway may have other implications for the function of endothelial cells. Since VEGF and thrombin increase the permeability of endothelial cell monolayers, the finding that both of these factors stimulate p125FAK tyrosine phosphorylation suggests that this pathway, possibly in conjunction with tyrosine phosphorylation-mediated disruption of adherens junction integrity, is involved in the regulation of endothelial permeability. VEGF has recently been shown to act as a survival factor for endothelial cells by preventing apoptosis (90). In this context, recent findings suggesting that p125FAK can suppress "anoikis," a subset of apoptosis induced in epithelial and endothelial cells (91, 92), raises the intriguing possibility that the p125FAK pathway may also participate in VEGF-induced signaling related to cell survival. Regardless of the precise functional role(s) of the p125FAK pathway in the endothelium, these results identify p125FAK and paxillin as components in a signal transduction pathway in the action of VEGF that may be a point of convergence in the regulation of several key endothelial cell functions, all of which are critically dependent upon interactions between the cell surface and the actin cytoskeleton.
We thank Rosario Cospedal for valuable assistance with MAP kinase assays.