Originally published In Press as doi:10.1074/jbc.M006274200 on August 16, 2000
J. Biol. Chem., Vol. 275, Issue 46, 36143-36151, November 17, 2000
cAMP-dependent Protein Kinase Phosphorylation of
EVL, a Mena/VASP Relative, Regulates Its Interaction with Actin
and SH3 Domains*
Anja
Lambrechts
§,
Adam V.
Kwiatkowski¶,
Lorene M.
Lanier¶
,
James E.
Bear¶**,
Joel
Vandekerckhove,
Christophe
Ampe, and
Frank B.
Gertler¶
From the Flanders Interuniversity Institute for
Biotechnology, Department of Medical Protein Chemistry, Faculty of
Medicine, Ghent University, Ledeganckstraat 35, 9000 Gent, Belgium and
the ¶ Department of Biology, Massachusetts Institute of
Technology, Cambridge, Massachusetts 02139-4307
Received for publication, July 14, 2000
 |
ABSTRACT |
Proteins of the Ena/VASP family are implicated in
processes that require dynamic actin remodeling such as axon guidance
and platelet activation. In this work, we explored some of the pathways that likely regulate actin dynamics in part via EVL
(Ena/VASP-like protein). Two
isoforms, EVL and EVL-I, were highly expressed in hematopoietic cells
of thymus and spleen. In CD3-activated T-cells, EVL was found in
F-actin-rich patches and at the distal tips of the microspikes that
formed on the activated side of the T-cells. Like the other family
members, EVL localized to focal adhesions and the leading edge of
lamellipodia when expressed in fibroblasts. EVL was a substrate for the
cAMP-dependent protein kinase, and this
phosphorylation regulated several of the interactions between EVL and
its ligands. Unlike VASP, EVL nucleated actin polymerization under
physiological conditions, whereas phosphorylation of both EVL and VASP
decreased their nucleating activity. EVL bound directly to the Abl,
Lyn, and nSrc SH3 domains; the FE65 WW domain; and profilin, likely via
its proline-rich core. Binding of Abl and nSrc SH3 domains, but not
profilin or other SH3 domains, was abolished by
cAMP-dependent protein kinase phosphorylation of EVL. We
show strong cooperative binding of two profilin dimers on the
polyproline sequence of EVL. Additionally, profilin competed with the
SH3 domains for binding to partially overlapping binding sites. These data suggest that the function of EVL could be modulated in a complex
manner by its interactions with multiple ligands and through phosphorylation by cyclic nucleotide dependent kinases.
| |
INTRODUCTION |
To respond properly to environmental cues, cells possess multiple
complex signal transduction networks. Many pathways lead to dynamic
changes of the actin cytoskeleton that form the basis for cell movement
in a wide variety of biological phenomena. In recent years, many
proteins participating in one or more signal transduction pathways have
been identified. One group of multifunctional proteins, involved in
actin-based motility, is the Ena/VASP family of proteins that include
Drosophila Ena (Enabled), Mena
(mammalian Ena), VASP
(vasodilator-stimulated
phosphoprotein), and EVL
(Ena/VASP-like protein) (1). Ena
was identified through genetic interactions with the
Drosophila Abl homologue (2, 3), whereas VASP was identified
as a prominent target for cAMP
(PKA)1- and
cGMP-dependent protein kinases in platelets (4). Mena and
EVL were identified by similarity to Ena (1). Ena, Mena, and VASP are
important in processes that require highly dynamic actin
reorganization, including axon guidance (5), platelet aggregation (6,
7), and fibroblast motility (8). The proteins are concentrated in
regions of the cell associated with movement and adhesion, including
the leading edge of lamellipodia, focal adhesions, and adherens
junctions (1, 9, 10).
The Ena/VASP proteins share a common domain structure that consists of
an amino-terminal Ena/VASP homology (EVH) 1 domain, a carboxyl-terminal
EVH2 domain, and a central proline-rich domain. The EVH1 domain is
highly conserved and binds to a target sequence that has the consensus
(E/D)FPPPPXDE (11, 12). Functional EVH1-binding motifs are
present in the Listeria monocytogenes surface protein ActA
(12); in the focal adhesion proteins vinculin and zyxin (13, 14); in
Fyb/SLAP (Fyn-binding
protein/SLP76-associated protein),
a component of the T-cell receptor pathway (15); and in the axon
guidance proteins ROBO (16) and
Semaphorin-6A-1.2 In
fibroblasts, the EVH1 domain mediates focal adhesion (1, 12, 17) and
leading edge targeting (8), and a functional EVH1 domain is required
for Ena function in Drosophila (18). The EVH2 domain
contains conserved motifs implicated in actin binding (9, 19, 20) and
formation of both homo- and heteromultimers of the Ena/VASP family
proteins (17, 18). In contrast to the highly conserved EVH1 and EVH2
domains, the central proline-rich domain of the different proteins
contains variable lengths of consecutive polyproline clusters. Three
types of ligands have been shown to bind to this region in Ena/VASP
proteins: the SH3 and WW domains and the actin-binding protein profilin
(1, 3, 18, 21, 22).
Several lines of evidence suggest that the interactions between
profilin and Ena/VASP proteins are important in vivo. In
mice, there is a potent dosage-sensitive genetic interaction between Mena and profilin I (5). Although Mena mutants are viable, displaying
defects in several nerve fiber tracts in the brain, a reduction of
profilin levels by 50% causes Mena mutants to exhibit a severe defect
in closure of the cephalic portion of the neural tube. In
Drosophila, mutations in Ena and profilin have each been shown to exhibit dosage-sensitive genetic interactions with Abl (2,
23). Despite this genetic evidence, the mechanisms that regulate the
interaction and function of Ena/VASP-profilin complexes remain poorly
understood (24).
The third member of the Ena/VASP family, EVL, has not been functionally
characterized. EVL partially restores Listeria movement in
cell-free extracts depleted of VASP and Mena (20) and shares many structural features with the other family members. The EVH1 domain
and distinct parts of the EVH2 domain are homologous, but the central
portion differs in both length and proline content. The number of
conserved cyclic nucleotide-dependent kinase
phosphorylation sites also differs; whereas VASP and Mena have three
and two, respectively, EVL has only one site (1). Although these
structural features suggest that the three mammalian proteins have
overlapping functions, we show here they may also have unique
properties and mechanisms of regulation. To gain further insight in the
regulatory pathways linked to actin dynamics, we studied the binding of
EVL to actin, profilin, and SH3 domains and the effect of PKA
phosphorylation on these interactions.
| |
EXPERIMENTAL PROCEDURES |
Protein Purification--
The coding region of EVL was amplified
from a mouse embryonic stem cell cDNA library. Murine VASP cDNA
was a kind gift of Dr. R. Fässler. Both cDNAs were cloned
into pFB-Nhis (Life Technologies, Inc.), and recombinant proteins were
obtained by using the Bac-to-BacTM baculovirus expression
system (Life Technologies, Inc.) according to the manufacturer's
instructions. The protein was purified on Talon resin
(CLONTECH) and subsequently dialyzed in PBS. The
SH3 domains were purified as GST fusion proteins from Escherichia coli lysates by affinity chromatography on glutathione-agarose (Amersham Pharmacia Biotech). Profilin IIa was purified from bovine brain as described (25). Recombinant profilins I and IIa were expressed
in E. coli and purified as
described.3 We prepared
skeletal muscle actin from rabbit muscle (26) and purified it by
Sephadex G-200 chromatography (27). Pyrene-labeled actin was
prepared as described (28).
Peptide Synthesis--
The EVL peptides were chemically
synthesized on a Model 431A peptide synthesizer (Applied Biosystems
Inc., Foster City, CA) and purified by reversed-phase high
pressure liquid chromatography. The mass and purity were
assessed by matrix-assisted laser desorption ionization time-of-flight
mass spectrometry. The proline-rich peptides are listed in Fig.
5. The actin-binding mimetic of the EVH2 domain has the
sequence
acetyl-C261GGGGLMEEMNKLLAKRRKAASQT283-OH.
Stable Transfection of Rat2 Fibroblasts with EVL and EVL-I
cDNAs--
EVL cDNA was cloned into the pNLSH vector, and
EVL-I cDNA into pIRES-EGFP. Retrovirus-containing supernatant
supplemented with 4 µg/ml Polybrene was added to Rat2 cells for
16 h at 32 °C. Subsequently, cells were placed at 37 °C; and
48 h after infection, selection was started by adding 5 mM histidinol to the medium. Cells were screened using
antibody staining of EVL.
Immunofluorescence--
Immunofluorescence staining of
Rat2 cells was performed essentially as described (1). Antibodies used
were polyclonal antibodies 1404 for EVL and 2197 for Mena and
monoclonal antibody 84A5 for EVL. Labeled secondary antibodies were
purchased from Jackson ImmunoResearch Laboratories, Inc.
Primary T-cell Isolation and Coverslip Activation--
Primary
T-cells were isolated and cultured as described (29).
Immunofluorescence staining was performed as described for Rat2 cells.
Phosphorylation of EVL in Cortical and Glial
Cultures--
Cortical and glial cultures were prepared as described
previously (5). Cells were rinsed in PBS and then lysed in radioimmune precipitation assay buffer (50 mM Tris, pH 8.0, 150 mM NaCl, 1% Triton X-100, 0.5% deoxycholate, and 0.1%
SDS), and protein concentrations were determined using the BCA assay
(Pierce). For in vitro kinase or phosphatase treatment, 10 µg of total protein were diluted 1:3 in the reaction buffer supplied
by the manufacturer (New England Biolabs Inc.) and incubated with
either 15 units of PKA or 1200 units of 
-phosphatase for 30 min at
30 °C. After incubation, samples were boiled in SDS-polyacrylamide
gel electrophoresis sample buffer and processed for Western blotting
using anti-EVL (1404) or anti-VASP (M4, immunoGlobe) polyclonal antibodies.
Phosphorylation and Dephosphorylation of EVL and VASP--
EVL
or VASP was incubated with PKA (New England Biolabs Inc.) in PKA buffer
(50 mM Tris-HCl and 10 mM MgCl2, pH
7.5) supplemented with 200 µM ATP and 10 µCi of
]
-32P[ATP for 30 min at 30 °C. Subsequently,
phospho-EVL was dialyzed in 50 mM Tris, 0.1 mM
EDTA, 5 mM dithiothreitol, and 2 mM
MnCl2, pH 7.5, and then treated with -phosphatase (New
England Biolabs Inc.) for 30 min at 30 °C.
Binding of EVL to SH3 Domains--
4 µg of EVL, phosphorylated
or dephosphorylated, were added to 50 µl of GST-SH3 fusion protein
bound to glutathione-agarose in PBS and 1% Triton X-100 and incubated
for 30 min at 4 °C. After three washes, the resin was boiled in 1×
SDS sample buffer for 5 min. One-tenth of the fraction was loaded onto
an 8% SDS-polyacrylamide gel (Bio-Rad) and, after transfer to
Hybond-Super, probed with monoclonal antibody 84A1 against EVL.
Analysis of the Binding Motif by the SPOTs
Method--
The membrane was probed as described (30).
BIAcore Analysis--
The BIAcore measurements were carried out
as described (31).
Solution Binding of EVL and Profilin--
EVL was immobilized on
Talon resin and incubated with an excess of profilin in 20 mM Tris-HCl, pH 8.1, 1 mM EDTA, and 1 mM dithiothreitol for 30 min at 4 °C. The resin was
washed several times and subsequently boiled in SDS sample buffer.
Competition Experiment--
GST-nSrc SH3 was bound to
glutathione-agarose beads and incubated with purified EVL for 30 min at
4 °C in PBS and 1% Triton X-100. Subsequently, a small column (50 µl) was made and washed twice with PBS and 1% Triton X-100, and then
profilin IIa was added in increasing concentrations as indicated. Equal
amounts of each eluted fraction were loaded onto SDS-polyacrylamide gel and subjected to Western blotting for EVL detection.
Actin Polymerization Assay--
For EVL, 4 µM
actin (7.5% pyrene-labeled) in G-buffer (5 mM Tris-HCl, pH
7.7, 0.2 mM ATP, 0.2 mM dithiothreitol, and 0.1 mM CaCl2) was supplemented with
MgCl2 and KCl to final concentrations of 2 and 100 mM, respectively. EVL was added to the concentrations indicated in the legend to Fig. 7 prior to measurement in a
Hitachi F-4500 spectrophotometer with excitation and emission
wavelengths set at 365 and 388 nm, respectively. For VASP, 1 µM Mg2+/ATP/actin in G-buffer without
CaCl2 was used. The polymerization was started by adding
MgCl2 and KCl to final concentrations of 2 and 15 mM, respectively, and 1 µM VASP.
| |
RESULTS |
EVL Localizes to Dynamic Regions in Fibroblasts and Activated
T-cells--
The subcellular distributions of Mena and VASP have been
well characterized in fibroblasts and several other cell types. Since fibroblasts lack detectable levels of EVL (see Fig. 2B), we
examined EVL distribution in primary T-cells, a rich source of EVL protein.
When primary CD4+ T-cells were plated on control antibody
(anti-CD71)-coated coverslips, EVL was mainly present in the cytoplasm of the cells (data not shown). Plating T-cells on anti-CD3
antibody-coated coverslips induced a clustering of the T-cell receptors
and subsequent activation of the polarization response. EVL became
localized in F-actin-rich patches that developed on the coverslip side
of the cell (Fig. 1A). In
addition to this actin patch localization, EVL could be detected at the
distal tips of microspikes that formed in response to T-cell receptor
cross-linking (Fig. 1A). Endogenous VASP (also expressed in
this cell type) showed a similar re-localization (data not shown). This
observation is consistent with a recent report demonstrating that
Ena/VASP proteins play a critical role in the actin reorganization that
occurs in activated Jurkat T-cells (15) and supports a model in which
their localization is regulated by specific signal transduction
pathways.
View larger version (48K):
[in this window]
[in a new window]
|
Fig. 1.
Endogenous EVL redistributes to sites of
actin polymerization in activated T-cells and fibroblasts.
A, primary CD4+ mouse T-cells were plated
on coverslips coated with anti-CD3 antibodies. Cells were allowed to
activate for 30 min and then fixed and stained with Oregon Green
488-phalloidin to localize F-actin and with anti-EVL monoclonal
antibodies. The lower panels show close-ups of the
boxed areas indicated in the upper panels.
B, Rat2 fibroblasts stably transfected with EVL cDNA
were stained with anti-EVL monoclonal and anti-Mena polyclonal
antibodies.
|
|
In fibroblasts, Mena and VASP are recruited to focal adhesions via
interactions with proteins containing the EVH1-binding motif (12). To
determine if EVL could be targeted by a similar mechanism, we generated
Rat2 fibroblasts that express EVL. Staining of these cells revealed
that EVL was concentrated in focal adhesions and at the leading edge of
the lamellipodium in a pattern very similar to Mena and VASP (Fig.
1B).
EVL Is Phosphorylated by PKA in Vitro and in Vivo--
VASP and
Mena have been shown to be substrates for PKA. Since only one of the
possible phosphorylation sites mapped in VASP is present in EVL
(Ser156) (Fig. 2A)
(1), we wanted to see if EVL is a substrate for PKA in vivo
and in vitro. Western blot analysis of EVL in adult mouse
organ extracts revealed two protein bands (Fig. 2B) (5). Similarly, two protein bands were observed in cultured cortical neurons, whereas mainly the upper band was detected in cultured glia
(Fig. 2C). In analogy with VASP and Mena (1, 32, 33), we
speculated that these two bands represent dephospho and phospho forms
of EVL. However, when cortical neuron and glial cell extracts were
treated with the catalytic domain of PKA in vitro, Western blot analysis indicated that both protein bands showed a small shift
upward rather than the expected shift of the lower form into the slower
migrating form (Fig. 2C). We note that the shift seen for
PKA-phosphorylated VASP in glial cells is larger than the one seen for
EVL (Fig. 2D). Treatment of the extracts in vitro with -protein phosphatase (-PPase) did not cause any detectable shift in either EVL band as compared with untreated extracts (Fig. 2C). In extracts of Rat2-EVL cells, a single EVL-reactive
band comigrated with the lower of the two bands found in spleen and brain (Fig. 2B), suggesting that the faster migrating form
is unlikely to be simply a proteolytic fragment of the slower migrating form.
View larger version (30K):
[in this window]
[in a new window]
|
Fig. 2.
Phosphorylation of EVL by PKA in
vitro and in vivo. A, shown
is the domain structure of EVL. The proline-rich sequence (amino acids
179-206) is indicated in single-letter notation. Serine 156 is the
conserved PKA phosphorylation site. The extra exon in EVL-I is located
between Ser339 and Arg340. B,
Western blotting of extracts from cultured cells and mouse organs with
polyclonal antibody 1404 against EVL revealed two major bands. In
Rat2-EVL and Rat2-EVL-I, the proteins on top of the major band are
probably phosphorylated forms, whereas breakdown products are also
seen. C, EVL exists in two isoforms in cortical neurons and
glial cells (EVL and EVL-I) that are both phosphorylated by PKA.
Untreated extracts (U) are compared with extracts treated
with either -PPase or PKA. D, shown is the VASP shift in
glial cell extracts treated with either PKA or -PPase. E,
shown are the results from the in vivo phosphorylation of
EVL. Rat2 cells were stimulated with forskolin for 10 min.
Phosphorylation of EVL is evident from the band shift noticed after
SDS-polyacrylamide gel electrophoresis and Western blotting of the
lysates. F, recombinant EVL (U) was treated with
either PKA or -PPase in vitro. G, shown is the
protein sequence of exon I in single-letter amino acid notation.
PLP, polyproline; p-VASP, phospho-VASP.
|
|
We reasoned that the upper form of EVL found in spleen and cortical
neurons might represent a larger isoform of EVL produced by the
inclusion of an additional exon. Sequence analysis of both the human
genomic locus of EVL as well as mouse expressed sequence tags predicted
the existence of an extra small exon. Therefore, it seems likely that
alternative splicing of the EVL mRNA produces two isoforms of EVL.
The shorter isoform contains the EVL sequence as described originally
(1). The larger protein, which we term EVL-I, contains an extra portion
that is 21 amino acids long and is located between Ser339
and Arg340 of EVL (Fig. 2, A and G).
Western blot analysis of Rat2 cells expressing a cDNA encoding
EVL-I indicated that this isoform comigrated with the larger signals
observed in spleen (Fig. 2B). The two isoforms displayed a
tissue-specific expression pattern (Fig. 2B) (5), and both
isoforms could be phosphorylated by PKA in vitro.
Although the EVH1 domain is necessary and sufficient for subcellular
targeting of Ena/VASP proteins, the EVH2 domain is also thought to play
a role in localization, perhaps by promoting more avid, multimeric
complexes (18). Since the extra sequence included in EVL-I falls in the
EVH2 domain, we expressed EVL-I in Rat2 cells to determine if
subcellular targeting might be affected by the additional sequence. The
staining pattern (Fig. 3) indicated that
EVL-I is localized in a pattern very similar to EVL, suggesting that
the extra sequence in EVL-I does not alter subcellular targeting under
these conditions.
View larger version (56K):
[in this window]
[in a new window]
|
Fig. 3.
Immunolocalization of EVL-I in transfected
Rat2 cells. Rat2-EVL-I cells were stained with monoclonal antibody
84A5 for EVL, polyclonal antibody 2197 for Mena, and Oregon Green-488
phalloidin. A, EVL-I localizes to focal adhesions and at the
end of stress fibers; B, overlapping localization of EVL-I
with Mena.
|
|
To assay whether EVL is also an in vivo substrate of PKA, we
stimulated the Rat2-EVL cells with forskolin, an activator of adenylyl
cyclase (34). After 10 min, cells were lysed and analyzed by Western
blotting. Forskolin induced a similar small band shift as PKA
treatment, indicating that EVL can be phosphorylated in vivo
by PKA (Fig. 2E).
For further experimental analysis of the effect of phosphorylation on
ligand binding, we purified EVL as a His6-tagged protein from the baculovirus expression system. The purified protein was phosphorylated in vitro with the catalytic subunit of PKA
and ATP. Typically, after 30 min, all EVL was phosphorylated, and the
observed shift was identical to the one seen with native EVL in cell
extracts (Fig. 2F). The shift could be reversed by
subsequent treatment with -PPase. We used these and similar samples
in the actin, profilin, and SH3 domain binding assays.
EVL Discriminates between Several SH3 Domains, and Phosphorylation
of EVL Affects Binding of Some SH3 Domains--
The central
proline-rich domain of EVL contains two separate proline-rich
sequences, P8VP4 and P6LP separated
by a TGST sequence (Fig. 2A), that contain possible binding
sites for SH3 domains (35, 36). To test whether EVL could bind to SH3
domains, several GST-SH3 fusion proteins (Fig.
4) were purified and incubated with EVL.
The formed complexes were pulled down with glutathione-agarose beads;
and after thorough washing, the beads were boiled in sample buffer and
analyzed by SDS-polyacrylamide gel electrophoresis. The results are
shown in Fig. 4 (upper panel). EVL bound robustly to the
Lyn, nSrc, and Abl SH3 domains. The Fyn, Src, and Crkl SH3
domains were poorly bound, whereas the Csk SH3 domain failed to bind
detectable levels of EVL. Therefore, EVL can bind to a distinct
repertoire of SH3 domains in vitro. The FE65 WW domain, which was previously shown to bind to Mena (22), also interacted with
EVL.
View larger version (36K):
[in this window]
[in a new window]
|
Fig. 4.
EVL binding to SH3 domains and effect of
phosphorylation. EVL bound to the indicated GST-SH3 fusion protein
was pulled down with glutathione-agarose. Upper panel,
recombinant EVL dephosphorylated with -PPase; middle
panel, recombinant EVL phosphorylated by PKA prior to SH3
domain binding; lower panel, recombinant EVL phosphorylated
by PKA and subsequently dephosphorylated by -PPase prior to SH3
domain binding. GST is a negative control with only GST bound to the
glutathione-agarose. Input is the amount of EVL added to the
different SH3 domains.
|
|
The interaction between Ena and the Abl SH3 domain is disrupted by
tyrosine phosphorylation of Ena (37), and specific interactions outside
the proline-rich core of ligands are also involved in SH3 domain
binding (38). Therefore, we wondered whether phosphorylation of EVL
might affect its ability to bind ligands through its proline-rich core
since the PKA site is located just in front of this portion of EVL
(Fig. 2A). We performed the same experiment as described above, except that the EVL protein was phosphorylated in
vitro by PKA prior to addition to the GST-SH3 proteins. The
results are shown in Fig. 4 (middle panel). The interaction
with both the nSrc and Abl SH3 domains was almost completely abolished
by PKA phosphorylation of EVL, whereas there was no or little effect on
the binding of EVL to the Lyn SH3 and FE65 WW domains. We observed no
effect on the non-interacting SH3 domains of Fyn, Src, Csk, and Crkl.
Reversing the phosphorylation event with -PPase restored the binding
properties of EVL to yield results identical to those of the original
experiment (Fig. 4, compare upper and lower
panels).
The Proline-rich Domain of EVL Binds with High Affinity to Profilin
IIa--
In addition to SH3 domains, profilin is also a ligand for the
proline stretches found in all other members of the Ena/VASP family (1,
18, 21). VASP preferentially binds profilin IIa in bovine brain
extracts containing both profilins I and IIa (39), and profilin IIa has
a >500-fold higher affinity for the (GP5)3
proline sequence derived from VASP compared with profilins I and IIb
(31).3 Therefore, we used profilin IIa to identify
sequences through which profilin binds to EVL. A SPOTs filter
containing overlapping 15-mer peptides that represent the entire EVL
sequence was incubated with purified profilin IIa. Bound profilin IIa
was detected with anti-profilin IIa antibodies (Fig.
5A). Two major binding sites could be identified that overlap with the proline-rich region: peptides
59-61 and 64-66. Interestingly, peptides 62 and 63, which also have a
high proline content, did not bind profilin, suggesting the specificity
of the interaction. Peptides 58 and 67 do not have enough proline
residues for binding of profilin. In addition to these two sites, a few
single peptides and one other non-proline region on the SPOTs filter
seemed to interact with profilin as well. The sequence spanning
peptides 9-13 is a conserved part in the EVH1 domain, and the same
region bound to profilin on a peptide scan with the Mena sequence.
However, when we tested a peptide overlapping this region on a BIAcore,
we did not observe any binding to profilin IIa (data not shown).
View larger version (58K):
[in this window]
[in a new window]
|
Fig. 5.
Profilin IIa is the preferred ligand for
EVL. A, a SPOTs filter containing 15-amino acid-long
peptides spanning the entire EVL sequence was probed with profilin IIa,
followed by detection with anti-profilin antibody. The dark
spots represent profilin IIa bound to peptides, and the sequences
of these peptides are shown below. Peptides displaying strong profilin
binding are in boldface. Some other peptides listed
(peptides 57, 58, 62, 63, and 67) do not bind, although they have
considerable proline content. B, shown are the results from
the BIAcore analysis of the interaction of profilins IIa and I with
peptides derived from the polyproline domain of EVL.
Rmax, theoretical maximum response units for the
peptides; S, number of profilin molecules bound to the
peptide; RUprofII, response unit value obtained
using 200 µM profilin IIa; RUprofI,
response unit value obtained with 190 µM profilin I;
N.T., not tested. Kd is the dissociation
constant for the profilin II-peptide interaction and is equal to the
concentration of profilin IIa that gives a response unit value equal to
Rmax/2. C, shown are the results from
the in-solution binding of phospho- and dephospho-EVL proteins to
profilins I and IIa. Immobilized EVL was incubated with profilin, and a
small column was poured (flow-through (F)). The column was
washed several times (Wash), and the resin was boiled
(R) to visualize the bound protein.
|
|
Based on the results from the peptide scan, we synthesized peptides
spanning the proline-rich region. The peptides had an amino-terminal
biotin group with which the peptides were coupled to a
streptavidin-coated BIAcore sensor chip. Surface plasmon resonance data
were collected for each peptide with a concentration series of
recombinant profilin IIa (Fig. 5B). From the surface plasmon
resonance data, both stoichiometry and dissociation constants (Kd) could be derived. Peptide A, containing the
entire polyproline sequence of EVL, bound four profilin molecules with an affinity of 0.3-0.4 µM. Peptides B and C, containing
the amino- and carboxyl-terminal parts of the polyproline sequence,
respectively, each bound two profilins with a lower affinity than
peptide A. This indicates that there is cooperativity between the two
sites on the polyproline domain of EVL. Peptide B has a fast
kon/koff (data not
shown), and its Kd is 160 times higher than that of
peptide A. Peptide D is similar to peptide C, but has the additional
VP4 part. However, this extra sequence does not change the
affinity or the number of bound profilin molecules. This is consistent
with the results from the SPOTs filter assay, where the peptides with
the valine in the middle and not more than four prolines on each side
of the valine did not bind profilin. Peptide E, in which the leucine is
replaced by another proline, has unexpectedly lower affinity for
profilin (Kd = 15 µM) than peptides D
and C, indicating that the leucine may play a role in optimizing the interaction.
The preference of EVL to bind to profilin IIa was also observed in a
solution binding assay (Fig. 5C). Immobilized dephospho- and
phospho-EVL proteins were incubated with recombinant profilin I or IIa.
After washing the columns, the resin was boiled and analyzed by
SDS-polyacrylamide gel electrophoresis. Consistent with the BIAcore
data, profilin I was not retained by the resin and therefore bound only
weakly to EVL under the assay conditions. The interaction of profilin
IIa was not affected by phosphorylation of EVL by PKA.
Profilin Competes with the nSrc SH3 Domain for EVL
Binding--
Since the SH3 domains and profilin both bind to the same
parts of the protein, we wondered if both could be bound
simultaneously. We bound EVL to GST-nSrc SH3-glutathione-agarose
and then exposed the column to increasing concentrations of profilin
IIa (Fig. 6). EVL was eluted from the
nSrc SH3 column when the profilin IIa concentration reached 2 µM. More EVL was eluted when higher concentrations of
profilin II were used. A similar result was obtained with the Abl SH3
domain and EVL and also with the Src and Abl SH3 domains and Mena (data
not shown). We conclude that EVL contains overlapping binding sites for
the nSrc SH3 domain and profilin and that profilin competes with the
SH3 domain for binding.
View larger version (27K):
[in this window]
[in a new window]
|
Fig. 6.
Profilin II competes with the nSrc SH3 domain
for EVL binding. EVL was bound to GST-nSrc
SH3-glutathione-agarose; and after washing the column, profilin II was
applied in increasing concentrations as indicated. Western blotting
with anti-EVL antibody 1404 showed the presence of EVL in the eluted
fractions. F, flow-through after loading the column;
W, buffer wash.
|
|
Dephospho-EVL Is a Potent Nucleator of Actin
Polymerization--
Ena/VASP family proteins have been implicated in
the regulation of actin dynamics. The recruitment of EVL to the F-actin
spots, its distinct localization at the tips of filopodia in activated T-cells, and its presumed role in actin cap formation in Jurkat T-cells
(Fig. 1A) (15) suggest that EVL is also involved in actin
assembly. Therefore, we assayed the ability of EVL to drive actin
nucleation and polymerization in vitro. Polymerization of 4 µM Ca2+/ATP/actin in G-buffer was initiated
by adding MgCl2 and KCl to final concentrations of 2 and
100 mM, respectively. Under these conditions and at this
actin concentration, polymerization was slow and had a long lag phase
(Fig. 7A, curve 1).
Addition of dephospho-EVL (1 µM) enhanced actin
polymerization immediately by strongly reducing the lag phase and
increasing the rate of polymerization. This resulted in a 3-fold higher
F-actin content after 30 min (Fig. 7A, curve 2).
Phospho-EVL was, however, less effective in enhancing polymerization.
It partially reduced the lag phase, but the rate of polymerization was
much slower then in the presence of dephospho-EVL (Fig. 7A,
curve 3). Similar results were obtained in independent
assays with different EVL and actin protein preparations. The effect
was concentration-dependent, as shown for dephospho-EVL in
Fig. 3B. We synthesized a peptide containing amino acids
261-283 of EVL. This sequence in EVL corresponds to a region in
the EVHZ domain of VASP shown to be important for actin binding
in vitro. (19). Preincubation of actin with 100 µM peptide-(261-283) inhibited the nucleating activity
of dephospho-EVL (Fig. 7A, curve 4). We conclude
that dephospho-EVL nucleates and enhances actin polymerization more
effectively than phospho-EVL and that nucleation can be inhibited by
adding a peptide mimicking the actin-binding region of the EVL EVH2
domain.
View larger version (14K):
[in this window]
[in a new window]
|
Fig. 7.
EVL and VASP nucleate actin polymerization
under different conditions. A, nucleating activity of
EVL. 4 µM Ca2+/ATP/G-actin was polymerized in
the absence or presence of 1 µM phospho- or
dephospho-EVL. Polymerization was started by adding MgCl2
and KCl to final concentrations of 2 and 100 mM,
respectively. Curve 1, 4 µM
Ca2+/ATP/G-actin; curve 2, 4 µM
Ca2+/ATP/G-actin with 1 µM dephospho-EVL;
curve 3, 4 µM Ca2+/ATP/G-actin
with 1 µM phospho-EVL; curve 4, 4 µM Ca2+/ATP/G-actin with 1 µM
dephospho-EVL and 100 µM peptide-(261-283).
B, dephospho-EVL induces actin polymerization in a
concentration-dependent manner. 4 µM
Ca2+/ATP/G-actin alone or with EVL (1, 0.5, and 0.25 µM) or -PPase was tested. Polymerization was initiated
as described for A. C, nucleating activity of
VASP. Curve 1, 1 µM
Mg2+/ATP/G-actin; curve 2, 1 µM
Mg2+/ATP/G-actin with 1 µM dephospho-VASP;
curve 3, 1 µM Mg2+/ATP/G-actin
with 1 µM phospho-VASP; curve 4, 1 µM Mg2+/ATP/G-actin with 1 µM
dephospho-VASP and 100 µM peptide-(261-283).
Polymerization was started by adding MgCl2 and KCl to 2 and
15 mM final concentrations, respectively. Inset,
dephospho-VASP (1 µM; filled circles) does not
nucleate actin polymerization (filled squares) under the
conditions used in A (4 µM
Ca2+/ATP/G-actin, 2 mM MgCl2, and
100 mM KCl).
|
|
We tested the ability of dephospho- and phospho-VASP proteins to
nucleate and enhance actin polymerization to obtain a direct comparison
of the ability of VASP and EVL to influence actin assembly in
vitro. Initially, dephospho-VASP was assayed under the same conditions as we used for EVL (4 µM
Ca2+/ATP/actin in G-buffer supplemented with 2 mM MgCl2 and 100 mM KCl); however,
significant polymerization of actin was not observed (Fig.
7C, inset). This result is in agreement with
published data showing that VASP nucleates polymerization of
Mg2+/ATP/actin only at low, nonphysiological salt
concentrations (20, 40). Under these low salt conditions (2 mM MgCl2 and 15 mM KCl), dephospho-VASP had strong nucleating activity, whereas phospho-VASP did
not nucleate actin polymerization (Fig. 7C). Note, however, that the ratio of VASP to actin was 1:1, whereas for EVL, this ratio
was 1:4, indicating that EVL nucleates actin polymerization more
efficiently than VASP. As with EVL, the nucleating activity of
dephospho-VASP was inhibited by addition of a 100-fold molar excess of
peptide-(261-283). We conclude that although the nucleating activities
of EVL and VASP differ, the activity of both can be regulated by phosphorylation.
| |
DISCUSSION |
The emerging picture from recent in vitro and in
vivo data suggests there is no simple linear signal transduction
cascade linking an extracellular signal to actin remodeling. Temporal and spatial fine-tuning of the regulation is necessary for the cell to
respond properly to extracellular signals. Networks of proteins and
protein-protein interactions are involved in this process, and many of
the interactions are regulated (41). We analyzed the interactions of
EVL with several of its binding partners, actin, profilin, and SH3
domains, and examined several possible mechanisms by which these
interactions might be regulated within cells.
During the course of this work, we discovered an alternatively spliced
variant (EVL-I) containing an insertion of 21 amino acids in the EVH2
domain of EVL. The expression of the two EVL isoforms is regulated in a
tissue-dependent manner, with EVL being the major form in
adult brain and EVL-I enriched in T-cells. Although alternatively
spliced variants of Mena have been identified, the resulting Mena
isoforms vary in the amino-terminal half of the protein (1). The
inclusion of an alternate exon in the EVH2 domain suggests that EVL-I
might cause alterations in the EVH2 domain functions such as
oligomerization and actin binding. It is also possible that the
additional insert in EVL-I might provide additional sites for
protein-protein interaction or regulation. In this regard, it is
interesting to note that the alternately included sequence contains two
KSP motifs that match the consensus for phosphorylation by Cdk5, a
kinase implicated in the regulation of neuronal migration (42-46).
Experiments to determine the functional differences between EVL and
EVL-I are in progress.
The Actin-nucleating Capacities of EVL and VASP Are
Different--
Our peptide inhibition assay indicated that actin
binding by EVL requires region B of the EVH2 domain, as expected from
sequence similarity to VASP (19). EVL and VASP can both support
actin-based Listeria motility (20); interestingly, however,
we found differences in the actin-binding properties of these two
highly related proteins. VASP induces actin polymerization only under
low salt conditions (this work and Refs. 20 and 40), whereas EVL
nucleates at both physiological and low salt concentrations (this
work). Differences in the actin-binding activities of EVL and VASP can
also be inferred from the observation that EVL can only partially
restore Listeria motility in VASP-depleted platelet extracts
(20).
The in vitro actin-nucleating activity of EVL is regulated
by phosphorylation. Dephospho-EVL is a better nucleator and enhancer of
actin polymerization than phospho-EVL, but phosphorylation does not
block the nucleating activity completely. Similar results were obtained
for VASP (under low salt conditions). The decrease in activity of
phospho-VASP was attributed to phosphorylation of serine 239 and/or
threonine 278, which are located close to and in the proposed
F-actin-binding region of VASP (amino acids 259-278) (19). In EVL,
these residues are changed to glutamine and alanine, respectively,
possibly explaining why phospho-EVL is not completely inhibited with
regard to its actin-nucleating capacity. However, we noted that serine
157, in the primary structure distant from the proposed actin-binding
site, still exerted some effect on actin nucleation. These data
indicate that, despite their extensive sequence similarity, the
proteins of the Ena/VASP family have different actin-binding properties
and may be differentially regulated (see also below).
EVL Binding to Profilin and Possible Implications for Actin
Dynamics--
The function of profilin binding to Ena/VASP proteins is
more enigmatic. Similar to VASP (39) and Aczonin (47), EVL is a
preferred partner of profilin IIa, the major profilin II isoform in
brain.3 The Ena/VASP proteins tend to form homo- and
hetero-oligomers and contain multiple profilin-binding sites, possibly
resulting in tethering of several profilin molecules to sites at which
they concentrate. The role of profilin may be rather passive by pooling actin monomers that are then shuttled to the EVH2 domain and used for
polymerization. Alternatively, a more active role may be possible. We
have shown that the combined sequestering effect of high profilin IIa
and thymosin 
4 concentrations is reversed when profilin IIa binds
the proline-rich sequence of VASP (31). Therefore, it is possible that
nucleation of actin polymerization by EVL could be enhanced in the
presence of profilin. Consistent with this are the observations that
addition of the VASP-derived proline-rich peptide arrests or
decelerates Listeria motility in PtK2 cells (48) and that
profilin is recruited only to motile Listeria in an
Ena/VASP-dependent manner (49). It is clear, however, that
Ena/VASP proteins can promote Listeria motility
independently of profilin (20, 50). Therefore, it is possible that
Ena/VASP proteins affect actin dynamics by both
profilin-dependent and -independent mechanisms. Preliminary
experiments to clarify the function of EVL-profilin complexes in actin
assembly indeed show very complex
kinetics.4
Regulation of SH3 Domain Binding--
SH3 domains have distinct
target specificities (51-55), and the polyproline domains of the
Ena/VASP proteins are the least conserved domains in these proteins.
This may permit them to interact with different SH3 domain-containing
proteins. The proline-rich domain of EVL binds to the SH3 domains of
Lyn, nSrc, and Abl and, to a lesser extent, to those of Fyn and Src. In
contrast, Mena binds only the Abl and Src SH3 domains out of >30
different SH3 domains tested
(1),5 and VASP binds the Abl
and Src SH3 domains (18). It is important to note that this is the
first report of a protein that binds stronger to the neuronal splice
variant nSrc SH3 domain than to the Src SH3 domain. Since EVL is
expressed in neuronal tissues (5), it may be a cellular partner of
nSrc. At present, it is unclear whether EVL and the nSrc SH3 domain
interact in a cellular context.
Profilin IIa and the FE65 WW and Abl SH3 domains bind to overlapping
regions of the proline-rich domain of EVL, illustrating the importance
of proline-rich motifs in signaling cascades (56). Interestingly, the
interaction of EVL with SH3 domains, but not with the FE65 WW domain or
profilin IIa, is regulated by PKA phosphorylation on
Ser156, a site close to the polyproline sequence. The
phosphorylation decreases the binding of the nSrc and Abl SH3 domains,
but not of the Lyn SH3 domain. These data suggest that extra regions
outside the proline-rich sequence are involved in this interaction (38, 52).
The role of the interaction of the Ena/VASP proteins with SH3
domain-containing proteins is still unresolved. SH3 domains may
function as simple recruitment factors, bringing the Ena/VASP proteins
to an appropriate location in the cell, or may play an active role in
signal transduction or actin modulation, similar to Grb2 and N-WASP
(neural Wiskott-Aldrich
syndrome protein) (57). In addition, due to
overlapping binding sites, competition of profilin and SH3 domains may
be an additional regulatory mechanism for providing access of SH3
domains to the polyproline domain. We suggest two possible scenarios
that are not necessarily mutually exclusive. First, PKA phosphorylation
of EVL promotes dissociation of the SH3 domain, whereas profilin can
still bind phospho-EVL. Second, a local increase in profilin
concentration may compete away bound SH3 domains. Such a system, in
combination with the different regulatory mechanisms of actin binding
discussed above, would allow fine-tuning of the function of the
Ena/VASP proteins.
EVL Localizes to Dynamic Actin Structures--
Immunolocalization
of EVL in transfected Rat2 cells shows that the protein is targeted to
the leading edge of the lamellipodium and the distal tips of stress
fibers, a pattern very similar to Mena and VASP. In activated primary
T-cells and Jurkat T-cells, EVL localizes to the F-actin collar and to
the distal tips of microspikes, two regions of dynamic actin
polymerization (this work and Ref. 15). The recruitment of EVL to the
T-cell receptor complex is mediated by Fyb/SLAP130, a molecule that was
recently identified as a ligand for Ena/VASP proteins (15). These data are also consistent with the recently reported observation that VASP
and Mena localize to tips of embedded filopodia and to puncta that
stabilize the contact with the neighboring cell during intercellular adhesion of epithelial cells (10). Together with their actin-nucleating activity, Ena/VASP proteins are ideally positioned to participate in
the development of polarized actin-rich structures in several cellular
processes. Depending on the cellular context, individual Ena/VASP
proteins may have specific functions. Reinforcing this idea, EVL, but
not Mena, could be immunoprecipitated with semaphorin-6A-1, a new
isoform of semaphorin-6, a member of a family of proteins that act as
ligands for axon guidance receptors.2
Ena/VASP Proteins: Involvement in Signaling and Actin
Remodeling--
The in vitro data presented in this work
demonstrate complex and highly regulated interactions between EVL and
its partners. EVL participates in several types of protein-protein
interactions involving actin, profilin, and signaling molecules such as
semaphorin-6A-1 2 and SH3 and WW domain-containing
proteins. The binding sites on EVL for profilin, WW domains, and SH3
domains overlap, and several of these interactions are selectively
modulated by PKA phosphorylation of EVL. Therefore, phosphorylation of
EVL in vivo could substantially alter both the capacity of
EVL to promote actin polymerization and the composition and activity of
multimeric protein complexes containing EVL. Activated PKA and
cGMP-dependent protein kinase are key regulators of the
guidance of migrating axonal and dendritic growth cones (58) and in
inhibition of the T-cell antigen response and of platelet activation
(4, 59, 60). In the latter two cases, this inhibition is accompanied by
inhibition of actin polymerization (4, 61), consistent with our
observation that phospho-EVL displays reduced and phospho-VASP displays
no nucleation of actin polymerization. In VASP-deficient mice,
inhibition of platelet aggregation is strongly reduced (7). In
addition, collagen-induced aggregation and shape change of VASP null
platelets occur faster than in wild-type platelets, although the extent
of shape change is identical in both types of platelets. One function
of VASP is therefore to inhibit the rate of platelet aggregation, and
this function is enhanced by phosphorylation of VASP by PKA and
cGMP-dependent protein kinase (6, 7). The role of VASP in
retarding the actin-driven process of platelet aggregation suggests
that Ena/VASP proteins may not always act to promote actin assembly
in vivo.
The function of Ena/VASP proteins in actin dynamics in living cells is
likely complex and context-dependent. Studies of fibroblast motility and lamellipodial extension may support this conclusion. Mitochondrial targeting of all Ena/VASP proteins within Rat2 cells results in an increase in the rate of lamellipodial extension and cell
motility. The same is observed in fibroblasts isolated from
Mena
/VASP/
mice, whereas overexpression of Mena or VASP leads to decreased rates
of lamellipodial extension and cell motility (8). It is possible either
that these phenotypes arise by Ena/VASP-mediated inhibition of actin
assembly or that Ena/VASP proteins regulate the formation of actin in a
way that inhibits cell motility, e.g. by driving actin
polymerization in a manner that does not promote productive
lamellipodial extension. How exactly the Ena/VASP proteins affect actin
polymerization in vivo is a question for future experiments. The many ligands for Ena/VASP proteins and possible regulatory mechanisms we have described provide new insights that should help to
elucidate the function of this protein family in controlling cell
motility and establishing cell morphology.
| |
ACKNOWLEDGEMENTS |
We thank Dr. R. Fässler for the kind
gift of the VASP cDNA and Dr. J. Wehland for the SPOTs filter. We
thank Veronique Jonckheere for help in the purification of the proteins
and Mark Goethals for peptide synthesis.
| |
Note Added in Proof |
After submission of this paper, Harbeck
et al. (Harbeck, B., Hüttelmaier, S., Schlüter,
K., Jockusch, B., and Illenberger, S. (2000) J. Biol. Chem.
275, 30817-30825) demonstrate that phosporylation of VASP
regulates its interaction with actin, corraborating our present work
with EVL. Using a yeast two-hyrid screen, we have identified Profilin I
as a binding partner of EVL, suggesting a potential interaction between
EVL and Profilin I could occur in vivo despite our inability
to detect binding in vitro (A. V. Kwiatkowski, D. Serna. and F. B. Gertler, unpublished results).
| |
FOOTNOTES |
*
This work was supported in part by National Institutes of
Health Grant GM58801 (to F. G.), Belgian Fund for National
Research Grants G006096 (to J. V.) and G004497 (to C. A.), GOA
Grant 91/96-3 (to J. V.), and a grant from the "Geneeskundige
stichting Koningin Elisabeth" (to C. A.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF279662.
§
Supported by a travel grant from the Belgian Fund for
National Research, Flanders.
Supported by National Institutes of Health Postdoctoral
Fellowship NS10655.
**
Supported by the Anna Fuller Molecular Oncology Fund.
To whom correspondence should be addressed: Dept. of Biology,
68-270, MIT, 77 Massachusetts Ave., Cambridge, MA 02139-4307. Tel.:
617-253-5511; Fax: 617-253-8699; E-mail: fgertler@mit.edu.
Published, JBC Papers in Press, August 16, 2000, DOI 10.1074/jbc.M006274200
2
Klostermann, A., Lutz, B., Gertler, F. B., and
Behl, C. (2001) J. Biol. Chem., in press.
3
Lambrechts, A., Braun, A., Jonckheere, V.,
Aszodi, A., Lanier, L. M., Robbens, J., Van Colen, I., Vandekerckhove,
J., Fassler, R., and Ampe, C. (2000) Mol. Cell. Biol., in press.
4
A. Lambrechts, C. Ampe, and F. B. Gertler,
unpublished results.
5
F. B. Gertler, unpublished results.
| |
ABBREVIATIONS |
The abbreviations used are:
PKA, cAMP-dependent protein kinase;
EVH, Ena/VASP homology;
PBS, phosphate-buffered saline;
GST, glutathione
S-transferase;
-PPase, -protein
phosphatase.
| |
REFERENCES |
| 1.
|
Gertler, F. B.,
Niebuhr, K.,
Reinhard, M.,
Wehland, J.,
and Soriano, P.
(1996)
Cell
87,
227-239
|
| 2.
|
Gertler, F. B.,
Doctor, J. S.,
and Hoffmann, F. M.
(1990)
Science
248,
857-860
|
| 3.
|
Gertler, F. B.,
Comer, A. R.,
Juang, J. L.,
Ahern, S. M.,
Clark, M. J.,
Liebl, E. C.,
and Hoffmann, F. M.
(1995)
Genes Dev.
9,
521-533
|
| 4.
|
Halbrugge, M.,
Friedrich, C.,
Eigenthaler, M.,
Schanzenbacher, P.,
and Walter, U.
(1990)
J. Biol. Chem.
265,
3088-3093
|
| 5.
|
Lanier, L. M.,
Gates, M. A.,
Witke, W.,
Menzies, A. S.,
Wehman, A. M.,
Macklis, J. D.,
Kwiatkowski, D.,
Soriano, P.,
and Gertler, F. B.
(1999)
Neuron
22,
313-325
|
| 6.
|
Hauser, W.,
Knobeloch, K. P.,
Eigenthaler, M.,
Gambaryan, S.,
Krenn, V.,
Geiger, J.,
Glazova, M.,
Rohde, E.,
Horak, I.,
Walter, U.,
and Zimmer, M.
(1999)
Proc. Natl. Acad. Sci. U. S. A.
96,
8120-8125
|
| 7.
|
Aszodi, A.,
Pfeifer, A.,
Ahmad, M.,
Glauner, M.,
Zhou, X. H.,
Ny, L.,
Andersson, K. E.,
Kehrel, B.,
Offermanns, S.,
and Fassler, R.
(1999)
EMBO J.
18,
37-48
|
| 8.
|
Bear, J. E.,
Loureiro, J.,
Libova, J. J.,
Fassler, R.,
Wehland, J.,
and ertler, F.
(2000)
Cell
101,
717-728
|
| 9.
|
Reinhard, M.,
Halbrugge, M.,
Scheer, U.,
Wiegand, C.,
Jockusch, B. M.,
and Walter, U.
(1992)
EMBO J.
11,
2063-2070
|
| 10.
|
Vasioukhin, V.,
Bauer, C.,
Yin, M.,
and Fuchs, E.
(2000)
Cell
100,
209-219
|
| 11.
|
Fedorov, A. A.,
Fedorov, E.,
Gertler, F.,
and Almo, S. C.
(1999)
Nat. Struct. Biol.
6,
661-665
|
| 12.
|
Niebuhr, K.,
Ebel, F.,
Frank, R.,
Reinhard, M.,
Domann, E.,
Carl, U. D.,
Walter, U.,
Gertler, F. B.,
Wehland, J.,
and Chakraborty, T.
(1997)
EMBO J.
16,
5433-5444
|
| 13.
|
Reinhard, M.,
Jouvenal, K.,
Tripier, D.,
and Walter, U.
(1995)
Proc. Natl. Acad. Sci. U. S. A.
92,
7956-7960
|
| 14.
|
Reinhard, M.,
Rudiger, M.,
Jockusch, B. M.,
and Walter, U.
(1996)
FEBS Lett.
399,
103-107
|
| 15.
|
Krause, M.,
Sechi, A. S.,
Konradt, M.,
Monner, D.,
Gertler, F. B.,
and Wehland, J.
(2000)
J. Cell Biol.
149,
181-194
|
| 16.
|
Kidd, T.,
Brose, K.,
Mitchell, K. J.,
Fetter, R. D.,
Tessier-Lavigne, M.,
Goodman, C. S.,
and Tear, G.
(1998)
Cell
92,
205-215
|
| 17.
|
Carl, U. D.,
Pollmann, M.,
Orr, E.,
Gertler, F. B.,
Chakraborty, T.,
and Wehland, J.
(1999)
Curr. Biol.
9,
715-718
|
| 18.
|
Ahern-Djamali, S. M.,
Comer, A. R.,
Bachmann, C.,
Kastenmeier, A. S.,
Reddy, S. K.,
Beckerle, M. C.,
Walter, U.,
and Hoffmann, F. M.
(1998)
Mol. Biol. Cell
9,
2157-2171
|
| 19.
|
Bachmann, C.,
Fischer, L.,
Walter, U.,
and Reinhard, M.
(1999)
J. Biol. Chem.
274,
23549-23557
|
| 20.
|
Laurent, V.,
Loisel, T. P.,
Harbeck, B.,
Wehman, A.,
Grobe, L.,
Jockusch, B. M.,
Wehland, J.,
Gertler, F. B.,
and Carlier, M. F.
(1999)
J. Cell Biol.
144,
1245-1258
|
| 21.
|
Reinhard, M.,
Giehl, K.,
Abel, K.,
Haffner, C.,
Jarchau, T.,
Hoppe, V.,
Jockusch, B. M.,
and Walter, U.
(1995)
EMBO J.
14,
1583-1589
|
| 22.
|
Ermekova, K. S.,
Zambrano, N.,
Linn, H.,
Minopoli, G.,
Gertler, F.,
Russo, T.,
and Sudol, M.
(1997)
J. Biol. Chem.
272,
32869-32877
|
| 23.
|
Wills, Z.,
Marr, L.,
Zinn, K.,
Goodman, C. S.,
and Van Vactor, D.
(1999)
Neuron
22,
291-299
|
| 24.
|
Lanier, L. M.,
and Gertler, F. B.
(2000)
Curr. Opin. Neurobiol.
10,
80-87
|
| 25.
|
Lambrechts, A.,
Van Damme, J.,
Goethals, M.,
Vandekerckhove, J.,
and Ampe, C.
(1995)
Eur. J. Biochem.
230,
281-286
|
| 26.
|
Spudich, J. A.,
and Watt, S.
(1971)
J. Biol. Chem.
246,
4866-4871
|
| 27.
|
Pardee, J. D.,
and Spudich, J. A.
(1982)
Methods Cell Biol.
24,
271-289
|
| 28.
|
Brenner, S. L.,
and Korn, E. D.
(1983)
J. Biol. Chem.
258,
5013-5020
|
| 29.
|
Zhang, J.,
Salojin, K.,
Gao, J. X.,
Cameron, M.,
Geisler, C.,
and Delovitch, T. L.
(1998)
J. Immunol.
161,
2930-2937
|
| 30.
|
Niebuhr, K.,
and Wehland, J.
(1997)
in
Immunology Methods Manual
(Lefkovits, I., ed)
, pp. 798-800, Academic Press Ltd., London
|
| 31.
|
Jonckheere, V.,
Lambrechts, A.,
Vandekerckhove, J.,
and Ampe, C.
(1999)
FEBS Lett.
447,
257-263
|
| 32.
|
Butt, E.,
Abel, K.,
Krieger, M.,
Palm, D.,
Hoppe, V.,
Hoppe, J.,
and Walter, U.
(1994)
J. Biol. Chem.
269,
14509-14517
|
| 33.
|
Smolenski, A.,
Bachmann, C.,
Reinhard, K.,
Honig-Liedl, P.,
Jarchau, T.,
Hoschuetzky, H.,
and Walter, U.
(1998)
J. Biol. Chem.
273,
20029-20035
|
| 34.
|
Seamon, K. B.,
and Daly, J. W.
(1981)
J. Cyclic Nucleotide. Res.
7,
201-224, and references therein
|
| 35.
|
Ren, R.,
Mayer, B. J.,
Cicchetti, P.,
and Baltimore, D.
(1993)
Science
259,
1157-1161
|
| 36.
|
Mayer, B. J.,
and Eck, M. J.
(1995)
Curr. Biol.
5,
364-367
|
| 37.
|
Comer, A. R.,
Ahern-Djamali, S. M.,
Juang, J. L.,
Jackson, P. D.,
and Hoffmann, F. M.
(1998)
Mol. Cell. Biol.
18,
152-160
|
| 38.
|
Feng, S.,
Kasahara, C.,
Rickles, R. J.,
and Schreiber, S. L.
(1995)
Proc. Natl. Acad. Sci. U. S. A.
92,
12408-12415
|
| 39.
|
Lambrechts, A.,
Verschelde, J. L.,
Jonckheere, V.,
Goethals, M.,
Vandekerckhove, J.,
and Ampe, C.
(1997)
EMBO J.
16,
484-494
|
| 40.
|
Huttelmaier, S.,
Harbeck, B.,
Steffens, O.,
Messerschmidt, T.,
Illenberger, S.,
and Jockusch, B. M.
(1999)
FEBS Lett.
451,
68-74
|
| 41.
|
Pawson, T.,
and Nash, P.
(2000)
Genes Dev.
14,
1027-1047
|
| 42.
|
Nikolic, M.,
Dudek, H.,
Kwon, Y. T.,
Ramos, Y. F.,
and Tsai, L. H.
(1996)
Genes Dev.
10,
816-825
|
| 43.
|
Nikolic, M.,
Chou, M. M.,
Lu, W.,
Mayer, B. J.,
and Tsai, L. H.
(1998)
Nature
395,
194-198
|
| 44.
|
Pigino, G.,
Paglini, G.,
Ulloa, L.,
Avila, J.,
and Caceres, A.
(1997)
J. Cell Sci.
110,
257-270
|
| 45.
|
Shetty, K. T.,
Link, W. T.,
and Pant, H. C.
(1993)
Proc. Natl. Acad. Sci. U. S. A.
90,
6844-6848
|
| 46.
|
Sharma, P.,
Barchi, J. J., Jr.,
Huang, X.,
Amin, N. D.,
Jaffe, H.,
and Pant, H. C.
(1998)
Biochemistry
37,
4759-4766
|
| 47.
|
Wang, X.,
Kibschull, M.,
Laue, M. M.,
Lichte, B.,
Petrasch-Parwez, E.,
and Kilimann, M. W.
(1999)
J. Cell Biol.
147,
151-162
|
| 48.
|
Kang, F.,
Laine, R. O.,
Bubb, M. R.,
Southwick, F. S.,
and Purich, D. L.
(1997)
Biochemistry
36,
8384-8392
|
| 49.
|
Geese, M.,
Schluter, K.,
Rothkegel, M.,
Jockusch, B. M.,
Wehland, J.,
and Sechi, A. S.
(2000)
J. Cell Sci.
113,
1415-1426
|
| 50.
|
Loisel, T. P.,
Boujemaa, R.,
Pantaloni, D.,
and Carlier, M. F.
(1999)
Nature
401,
613-616
|
| 51.
|
Rickles, R. J.,
Botfield, M. C.,
Weng, Z.,
Taylor, J. A.,
Green, O. M.,
Brugge, J. S.,
and Zoller, M. J.
(1994)
EMBO J.
13,
5598-5604
|
| 52.
|
Rickles, R. J.,
Botfield, M. C.,
Zhou, X. M.,
Henry, P. A.,
Brugge, J. S.,
and Zoller, M. J.
(1995)
Proc. Natl. Acad. Sci. U. S. A.
92,
10909-10913
|
| 53.
|
Alexandropoulos, K.,
Cheng, G.,
and Baltimore, D.
(1995)
Proc. Natl. Acad. Sci. U. S. A.
92,
3110-3114
|
| 54.
|
Songyang, Z.,
and Cantley, L.
(1995)
Trends Biochem. Sci.
20,
470-475
|
| 55.
|
Sudol, M.
(1998)
Oncogene
17,
1469-1474
|
| 56.
|
Kay, B. K.,
Williamson, M. P.,
and Sudol, M.
(2000)
FASEB J.
14,
231-241
|
| 57.
|
Carlier, M. F.,
Nioche, P.,
Broutin-L'Hermite, I.,
Boujemaa, R.,
Le Clainche, C.,
Egile, C.,
Garbay, C.,
Ducruix, A.,
Sansonetti, P. J.,
and Pantaloni, D.
(2000)
J. Biol. Chem.
275,
21946-21952
|
| 58.
|
Song, H. J.,
and Poo, M. M.
(1999)
Curr. Opin. Neurobiol.
9,
355-363
|
| 59.
|
Siess, W.,
and Lapetina, E. G.
(1990)
Biochem. J.
271,
815-819
|
| 60.
|
Skalhegg, B. S.,
Landmark, B. F.,
Doskeland, S. O.,
Hansson, V.,
Lea, T.,
and Jahnsen, T.
(1992)
J. Biol. Chem.
267,
15707-15714
|
| 61.
|
Selliah, N.,
Bartik, M. M.,
Carlson, S. L.,
Brooks, W. H.,
and Roszman, T. L.
(1995)
J. Neuroimmunol.
56,
107-112
|
Copyright © 2000 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
|
|
 
P. M. Benz, C. Blume, J. Moebius, C. Oschatz, K. Schuh, A. Sickmann, U. Walter, S. M. Feller, and T. Renne
Cytoskeleton assembly at endothelial cell cell contacts is regulated by {alpha}II-spectrin VASP complexes
J. Cell Biol.,
January 10, 2008;
180(1):
205 - 219.
[Abstract]
[Full Text]
[PDF]
|
|
|
TOP
ABSTRACT
INTRODUCTION
