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Molecular and Cellular Biology, October 2000, p. 7591-7601, Vol. 20, No. 20
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Abl Interactor 1 Binds to Sos and Inhibits
Epidermal Growth Factor- and v-Abl-Induced Activation of Extracellular
Signal-Regulated Kinases
Pang-Dian
Fan1 and
Stephen P.
Goff2,*
Integrated Program in Cellular, Molecular and
Biophysical Studies,1 and Howard Hughes
Medical Institute and Department of Biochemistry and Molecular
Biophysics,2 Columbia University College of
Physicians & Surgeons, New York, New York 10032
Received 30 December 1999/Returned for modification 15 February
2000/Accepted 31 July 2000
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ABSTRACT |
Recent studies have suggested that members of the Abl interactor
(Abi) protein family negatively regulate cell growth and transformation. To date, however, no specific role in these cellular processes has been identified for the Abi family. Here we describe the
inhibition by overexpressed Abi-1 of a mitogenic pathway activated by
both growth factors and v-Abl. We have identified the guanine nucleotide exchange factors Sos1 and Sos2 as novel binding partners of
Abi-1. A domain that is required for interaction with Sos in vivo has
been mapped to the amino terminus of Abi-1. Overexpression of Abi-1
inhibits epidermal growth factor (EGF)-induced activation of
extracellular signal-regulated kinases (Erks) but does not affect
EGF-induced activation of c-Jun N-terminal kinase or Akt. In addition,
overexpression of Abi-1 blocks Erk activation induced by v-Abl. In both
cases, the maximal inhibitory effect requires an intact amino-terminal
Sos-binding domain in Abi-1. Finally, we demonstrate that tyrosine
phosphorylation of endogenous Abi-1 in fibroblasts is induced by both
v-Abl and serum stimulation, further suggesting a role for Abi-1 in
signal transduction initiated by v-Abl and growth factors. Taken
together, these findings suggest that overexpressed Abi proteins
negatively regulate cell growth and transformation by specifically
targeting the Erk pathway.
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INTRODUCTION |
Abl interactor (Abi) proteins were
originally identified as binding partners of the Abl nonreceptor
tyrosine kinase (5, 28). The two members of the Abi family,
Abi-1 and Abi-2, are highly homologous. Both contain an amino-terminal
homeobox-like domain, proline-rich regions, PEST sequences, and a
carboxy-terminal SH3 domain. Mapping of interaction sites on both Abl
and Abi indicates that reciprocal binding occurs: the SH3 domain of
each protein binds to a proline-rich motif on the partner molecule
(5). Overexpression of Abi-1 lacking amino acids 1 to 85 (Abi
1-85), originally reported as the full-length protein, was
shown to inhibit transformation of fibroblasts by full-length
p160v-abl but not by v-Src (28). This
deletion mutant of Abi-1 also failed to inhibit the transforming
activity of truncated p90v-abl, correlating with
the inability of Abi-1 to physically associate with
p90v-abl. Recently, we have found in similar
assays that full-length Abi-1 can inhibit the transforming activity of
p160v-abl (A. Ikeguchi and S. P. Goff,
unpublished data). Overexpression of a truncated form of Abi-2
that retained only one Abl-binding site was found to potentiate
c-Abl-transforming activity (5). More recently
identification of Eps8 and spectrin as additional interaction
partners of Abi-1 provided potential links to growth factor
receptor-mediated signaling and the cytoskeleton (2, 36). In
addition, oncogenic forms of Abl and Src
namely, BCR-ABL and
v-Srchave been found to target Abi proteins in a Ras-independent manner for ubiquitin-dependent proteolysis (6). Expression of Abi proteins is also lost in the bone marrow cells of patients with
aggressive BCR-ABL-positive leukemias, suggesting that the loss of Abi
expression contributes to progression of disease. Taken together, these
findings suggest that Abi proteins may act as negative regulators of
cell growth and transformation.
The mechanism by which Abi-1 overexpression suppresses
v-Abl-transforming activity has not been elucidated.
p160v-abl, encoded by the Abelson murine
leukemia virus, is a chimeric protein consisting of the amino-terminal
region of Moloney murine leukemia virus Gag and the SH2, SH1, and
carboxy-terminal domains of c-Abl. Similar to BCR-ABL and TEL-ABL,
v-Abl displays constitutive tyrosine kinase activity that is required
for transformation (19). However, Abi proteins do not appear
to directly inhibit Abl kinase activity (28, 33), and it has
been proposed that the binding of Abi-1 to v-Abl might block activation
of critical signal transduction pathways. Signaling molecules activated
downstream of v-Abl include Ras (26), phosphatidylinositol
3-kinase (PI3K) (30), Rac (25), c-Jun N-terminal
kinase (JNK) (21, 25), extracellular signal-regulated kinases (Erks) (21, 25), protein kinase C (18),
Janus kinases (7, 8), and signal transducers and activators
of transcription (7, 8). In particular, Ras activity has
been demonstrated to be necessary for v-Abl-mediated transformation
(26). In addition, activation of several of the
aforementioned signaling proteins requires functional Ras.
It is still unclear which signaling proteins are responsible for
coupling v-Abl kinase activity to Ras activation. Ras activation normally occurs upon recruitment of the Ras-specific guanine nucleotide exchange factor (GEF) Son of sevenless (Sos) to the plasma membrane in
close proximity to Ras. For example, autophosphorylation of activated
receptor tyrosine kinases can create membrane-localized docking sites
for Grb2-Sos or Shc-Grb2-Sos complexes. Subsequent activation of Ras
can trigger multiple signaling events, including the well-characterized
Raf-Mek-Erk kinase cascade. Targeting Sos to the plasma membrane by
addition of myristoylation or farnesylation signals to Sos is
sufficient to activate Ras-dependent signaling (1). Since
the Gag moiety of v-Abl can direct localization to the plasma membrane,
recruitment of Sos to v-Abl might be sufficient for Ras activation.
Multiple Abl-binding proteins potentially link v-Abl to Sos. The SH2
domain of v-Abl interacts with Shc in a non-phosphotyrosine-dependent
manner and can recruit Shc-Grb2-Sos complexes (20). In
addition, the carboxy-terminal domain of v-Abl contains three
proline-rich motifs that are docking sites for the Sos-binding Crk,
Nck, and Grb2 adapter proteins (23). Dominant negative
mutants of Grb2 and CrkI inhibit Erk activation induced by oncogenic
Abl, suggesting that these adapter proteins participate in a positive
manner in v-Abl-induced Ras signaling (29). In addition,
v-Abl binds and phosphorylates p62dok, promoting
the association of p62dok with RasGAP. It is not
yet known whether this interaction inhibits the ability of RasGAP to
negatively regulate Ras. However, overexpression of DOKL, a Dok-like
protein, can inhibit v-Abl-induced Erk activation and transformation,
suggesting a role for Dok proteins in v-Abl-induced Ras signaling
(4). Therefore, it is possible to inhibit both v-Abl- and
growth factor-mediated Ras-dependent signaling by interfering with the
localization or function of regulatory, adapter, or effector components
of the Ras pathway.
To investigate the potential role of Abi-1 in cell growth and
transformation, we have sought additional Abi-1 interaction partners
that might be modulators or effectors of Abi-1 functions. Here we
describe the identification of the mammalian Sos proteins as novel
binding partners for Abi-1. We demonstrate that the amino terminus of
Abi-1 is necessary for this interaction in vivo. Overexpression of
Abi-1 inhibits a specific epidermal growth factor (EGF)-induced signaling event downstream of Sos and Ras, namely, the activation of
Erks. In addition, we show that overexpression of Abi-1 can block
v-Abl-induced Erk activation. Thus, our work identifies a potential
negative regulatory role for Abi proteins in a specific mitogenic
pathway activated by both growth factors and v-Abl. Our findings also
suggest possible mechanisms for the previously observed inhibition of
v-Abl-mediated transformation by overexpression of Abi-1. A role for
Abi-1 in v-Abl- and growth factor-mediated signaling in fibroblasts is
further suggested by the induction of tyrosine phosphorylation of
endogenous Abi-1 by both v-Abl and serum stimulation.
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MATERIALS AND METHODS |
Yeast two-hybrid screening.
A cDNA sequence encoding amino
acids 394 to 475 of murine Abi-1 was amplified by PCR using pCGN-Abi-1
as the template. The oligonucleotides for PCR were
5'-GAAGATGGGATCCCTGCAGTAGTTCAGT-3' and
5'-CTCTCCGTCGACCTAATCAGTATAGTGCAT-3' (where
BamHI and SalI sites are underlined). To create
the bait plasmid pSH2-AbiSH3, the amplified fragment was digested with
BamHI and SalI and cloned into the
Saccharomyces cerevisiae expression vector pSH2-1 in frame
with the LexA DNA-binding domain (LexADBD). To construct the plasmid
AGP5 encoding the LexADBD-Abl hybrid, type 1 c-abl cDNA was
partially digested with BglII. A
BglII-BglII fragment encoding amino acids 4 to
1087 of type 1 c-abl was inserted into pSH2-1. This insert
was released by BglII digestion and cloned into the yeast
expression vector pGADNOT to generate the Gal4 activation domain
(Gal4AD)-Abl construct. Yeast two-hybrid screening of the WEHI-3 cDNA
library cloned into pGADNOT was performed as described previously
(28). DNA sequencing and sequence analysis were also
performed as described previously (28).
Mammalian expression constructs.
Myc-tagged constructs were
created by cloning various cDNA fragments of murine abi-1,
murine type IV c-abl, and human granulocyte-macrophage colony-stimulating factor (GM-CSF) receptor 
chain into the
EcoRI and SrfI sites of the mammalian expression
vector MT21myc in frame with the myc epitope at the 3' end of the
cloning site. To generate hemagglutinin (HA)-tagged constructs, various
fragments of murine abi-1 and human SOS1 cDNAs
were cloned into the mammalian expression vector pCGN in frame with the
HA epitope at the 5' end of the cloning site. The HA-tagged DOKL
construct has been described previously (4). To create the
HA-Sos2(874-1297) construct, a DNA fragment encoding amino acids 874 to 1297 of murine Sos2 was released from the Gal4AD-Sos2 hybrid plasmid
by digestion with SpeI and BglII and cloned into
pCGN. SR, SR-HA-Erk2, and SR-HA-JNK were gifts from Audrey
Minden (Columbia University, New York, N.Y.). The plasmids pCMV-6 and
pCMV-6-HA-Akt were donated by Thomas Franke (Columbia University). The
v-Abl expression vector pcDNA-p160v-abl was
shared with us by Paul Rothman (Columbia University). The kinase-dead
v-Abl mutant expression vector pcDNA-p160v-abl
(KD) was constructed by swapping a BstEII-BspEI
fragment from pGD-v-Abl (KD) (courtesy of David Baltimore) into
pcDNA-p160v-abl. A plasmid encoding the
v-Src oncogene under the control of the simian virus 40 early promoter was a gift from A. Levinson (Genentech, Inc., South San
Francisco, Calif.).
Cell culture and transfections.
COS cells and 293T cells
were maintained in Dulbecco modified Eagle medium (DMEM) supplemented
with 10% fetal bovine serum (FBS), 2 mM L-glutamine, and
antibiotics. D5 (courtesy of Jean Wang, University of California, San
Diego) and BALB/c3T3 cells were maintained in DMEM supplemented with
10% calf serum (CS), 2 mM L-glutamine, and antibiotics. D5
cells were maintained at 39°C. Parental BAF/3 cells and BAF/3 cells
stably transfected with p160v-abl (7)
were maintained in RPMI 1640 medium supplemented with 10% FBS, 5%
WEHI-3 supernatant, 5 µM 
-mercaptoethanol, 1 mM sodium pyruvate,
and 1 mM L-glutamine. COS cells were transfected with 10 µg of DNA per 2 × 106 cells by the chloroquine
DEAE-dextran method (22). 293T cells were transfected with 8 µg of DNA per 2 × 106 cells by the standard calcium
phosphate precipitation method. The total amount of DNA per
transfection was normalized using empty vector controls.
Antibodies.
Polyclonal antibodies against Sos1-Sos2, Sos1,
and Sos2, and monoclonal antibody against c-Myc (9E10) were purchased
from Santa Cruz Biotechnology. Anti-Grb2 (Transduction Laboratories) and anti-EGF receptor (EGFR) (Upstate Biotechnology) monoclonal antibodies were used for immunoprecipitation. Polyclonal antibodies against Grb2 and EGFR (Santa Cruz Biotechnology) were used for Western
blot analysis. Anti-HA monoclonal antibody was obtained from Boehringer
Mannheim and BAbCO. Anti-ACTIVE mitogen-activated protein kinase and
anti-Abl antibodies were purchased from Promega and PharMingen,
respectively. PhosphoPlus JNK and Akt antibody kits were obtained from
New England Biolabs. Monoclonal antibodies against Eps8 and
phosphotyrosine were purchased from Transduction Laboratories.
Polyclonal antibodies against Abi-1 were described previously
(28).
Fusion proteins and in vitro binding assays.
A cDNA fragment
encoding amino acids 385 to 475 of Abi-1 was inserted into the
bacterial expression vector pMAL-c2 (New England Biolabs) in frame with
sequences coding for maltose-binding protein (MBP). Bacterial lysates
containing the fusion proteins were prepared as previously described in
TNENI (50 mM Tris-HCl [pH 7.5], 50 mM NaCl, 10 mM EDTA, 0.5% NP-40,
1 mM phenylmethylsulfonyl fluoride, 10 µg of aprotinin per ml, 10 µg of leupeptin per ml, 1 µg of pepstatin per ml) and incubated
with amylose resin (New England Biolabs) for 1 h at 4°C. The
resin was washed four times in lysis buffer, incubated with mammalian
cell lysate for 1 h at 4°C, and again washed four times in lysis
buffer. Bound proteins were boiled in 2× Laemmli buffer and resolved
by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)
for either staining with Coomassie brilliant blue or transfer to an
Immobilon-P membrane (Millipore). Membrane-bound proteins were
subjected to Western blot analysis as described below.
Growth factor deprivation and stimulation.
For serum
starvation, COS and 293T cells were washed 16 to 24 h after
transfection and incubated in 0.2% FBS for 24 to 30 h.
Stimulation with recombinant human EGF (Upstate Biotechnology) was at a
concentration of 100 ng/ml for the specified times. For tyrosine
phosphorylation studies, BALB/c3T3 and D5 cells were serum starved in
0.5% CS for 24 and 48 h, respectively. Serum-starved BALB/c3T3
cells were stimulated with 20% FBS in DMEM for the indicated times.
Parental BAF/3 cells and BAF/3 cells stably transfected with
p160v-abl were starved in 0.5% FBS for 8 h
prior to stimulation at a concentration of 108 cells/ml
with 50 ng of recombinant murine interleukin-3 (IL-3) (Sigma) per ml.
Immunoprecipitation and Western blot analysis.
Cells for
coimmunoprecipitation experiments were washed in phosphate-buffered
saline (PBS)-PI (PBS plus 0.4 mM Na3VO4 and 0.4 mM EDTA) and lysed in TNENI plus 10 mM NaF and 1 mM
Na3VO4. Cells for Erk2, JNK, Akt, and tyrosine
phosphorylation assays were washed in PBS-PI and solubilized with lysis
buffer (20 mM Tris-HCl [pH 8], 138 mM NaCl, 10% glycerol, 1% NP-40,
2 mM EDTA, 10 mM NaF, 1 mM Na3VO4, 1 mM
phenylmethylsulfonyl fluoride, 10 µg of aprotinin per ml, 10 µg of
leupeptin per ml, and 1 µg of pepstatin per ml). Lysates were
incubated at 4°C for 20 min and clarified for 20 min at
14,000 × g and 4°C. Lysates were rocked with
antibodies for 1 h at 4°C and for an additional hour with either
protein A-agarose or protein G PLUS-agarose (Santa Cruz Biotechnology).
The agarose beads were washed four times with lysis buffer and boiled
in 2× Laemmli buffer. Eluted proteins were resolved by SDS-PAGE,
transferred to an Immobilon-P membrane, and subjected to Western blot
analysis as described previously using ECL and ECL Plus detection
systems (Amersham) (9). Bands in Figure 4 were quantitated
using a densitometer. The amount of active HA-Erk2 at each time point
was normalized to the total amount of HA-Erk2. The normalized amount of
active HA-Erk2 in unstimulated cells transfected with the empty vector
control was assigned a relative value of 1.0.
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RESULTS |
Interaction of Abi-1 and Sos2 in yeast.
To identify proteins
that interact with Abi-1, we used the yeast two-hybrid system to screen
for proteins that bind to the Abi-1 SH3 domain. The bait plasmid
pSH2-AbiSH3 encoding a fusion of the LexADBD and the Abi-1 SH3 domain,
was used to screen a library of cDNAs derived from the mouse
myelomonocytic leukemia WEHI-3 cell line and expressed as fusions to
the Gal4AD. Thirty positive clones were isolated from a screen of
approximately 600,000 yeast colonies cotransformed with bait and
library plasmids. Four of these clones contained sequences encoding
carboxy-terminal domains of the Ras-specific guanine nucleotide
exchange factor Sos2. Two Gal4AD-Sos2 hybrids including different
carboxy-terminal fragments of Sos2 were each isolated twice. Both
hybrids contain all the proline-rich motifs that bind the SH3 domains
of Grb2 (34). Neither hybrid includes the Dbl and pleckstrin
homology domains or an intact Ras-specific GEF catalytic region of
Sos2. Results from the yeast two-hybrid experiments are summarized in Table 1.
Association of Abi-1 and Sos in vitro.
We performed in vitro
binding assays to confirm the interaction observed in the yeast
two-hybrid system. A fusion protein comprised of MBP and the Abi-1 SH3
domain was tested for binding to Sos proteins from mammalian cell
lysates. Bacterially expressed MBP and MBP-Abi SH3 were purified on
amylose resin and incubated with various cell extracts. Bound proteins
were eluted, resolved by SDS-PAGE, and immunoblotted with antibodies
that recognize Sos1, Sos2, or both Sos1 and Sos2. As shown in Fig.
1A, MBP-Abi SH3, but not MBP, was able to
precipitate both Sos1 and Sos2 from BALB/c3T3 cell lysates. Similar
results were obtained with extracts from WEHI-3 and NIH 3T3 cells (data
not shown). To address the specificity of this interaction with MBP-Abi
SH3, we compared the binding to Sos2 with the binding to two other
proteins containing multiple PXXP motifs, the
p62dok-like protein DOKL and Abi-1 itself. Cell
extracts were prepared from COS cells expressing each of the truncated
or full-length proteins tagged with an HA epitope. Resin-bound MBP-Abi
SH3, but not resin-bound MBP, was repeatedly able to precipitate a
protein consisting of amino acids 874 to 1297 of Sos2 from total cell lysates, even those containing barely detectable levels of this Sos2
fragment (Fig. 1B). No binding to MBP-Abi SH3 was detected with amino
acids 86 to 475 of Abi-1 or with full-length DOKL. These data indicate
that the association in vitro between the Abi-1 SH3 domain and Sos is
specific.
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FIG. 1.
In vitro binding of the Abi-1 SH3 domain to Sos. (A) MBP
and MBP-Abi SH3 immobilized on amylose resin were incubated with
BALB/c3T3 cell lysate. Bound proteins were immunoblotted with
antibodies that recognize both Sos1 and Sos2 (Sos1/2) (top). The
membrane was stripped and reprobed with anti-Sos1 (middle) and
anti-Sos2 (bottom) antibodies. Total cell lysate and anti-Sos1 and
-Sos2 immunoprecipitate (IP) from BALB/c3T3 cells were included for
reference. WB, Western blot. (B) COS cells were transiently transfected
with plasmids encoding HA-tagged DOKL, Abi(1-85), or
Sos2(874-1297) [Sos2(C)]. Cell lysates were incubated with MBP and
MBP-Abi SH3 as described for panel A. Total cell lysates and bound
proteins were probed with anti-HA antibody (upper). HA-Sos2(874-1297)
expression in the total cell lysate was detected upon longer exposure.
A fraction of the resin eluate was stained with Coomassie brilliant
blue to confirm roughly equivalent amounts of MBP and MBP-Abi SH3
(lower).
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Interaction of Abi-1 and Sos in vivo.
To determine whether
Abi-1 and Sos can interact in vivo, we tested the ability of myc
epitope-tagged Abi-1 to coimmunoprecipitate with endogenous Sos in COS
cells. Plasmids encoding various myc-tagged proteins were transfected
into COS cells. Cell lysates were prepared, and proteins were
immunoprecipitated with antibodies that recognize both Sos1 and Sos2.
Immunoprecipitates were then subjected to SDS-PAGE and Western blot
analysis with anti-myc antibody. As illustrated in Fig.
2A, both Abi-1 and Abi328-356, a
shorter form generated by alternative splicing, coimmunoprecipitated
with endogenous Sos proteins. In contrast, neither c-Abl nor the GM-CSF receptor chain bound to Sos. These results demonstrate that Sos can
associate specifically with Abi-1 in vivo.
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FIG. 2.
Interaction between Abi-1 and Sos in COS cells. (A) COS
cells were transiently transfected with plasmids encoding myc-tagged
GM-CSF receptor chain, c-Abl, Abi-1, or Abi328-356. Sos1 and
Sos2 were immunoprecipitated from cell lysates. Precipitated proteins
(top) were immunoblotted with anti-myc antibody (myc). The membrane
from the top blot was reprobed with anti-Sos1 and -Sos2 antibodies to
confirm equal levels of protein loading (middle). Total cell lysates
were probed with anti-myc antibody to confirm expression of myc-tagged
proteins (bottom). IP, immunoprecipitate; WB, Western blot. (B)
Schematic representation of full-length (FL) Abi-1 and deletion mutant
proteins used in panel C. The homeobox-like domain, proline-rich
motifs, polyproline region, and SH3 domain are indicated. (C) COS cells
were transiently transfected with plasmids encoding myc-tagged
full-length Abi-1 or the indicated deletion mutant proteins. Proteins
were immunoprecipitated from cell lysates with anti-Sos1 and -Sos2
antibodies and were analyzed as described for panel A. The asterisk
indicates the position of the immunoglobulin heavy chain.
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We next mapped the interaction domain on Abi-1 by testing various
myc-tagged deletion mutant proteins of Abi-1 for binding
to endogenous
Sos. It should be noted that the cDNA clone previously
reported as
full-length Abi-1 (
28) was truncated at the 5' end;
this
clone is now defined as encoding a deletion mutant lacking
amino acids
1 to 85. Full-length Abi-1 sequences were isolated
by rapid
amplification of cDNA ends and cloned into expression
vectors (A. Ikeguchi and S. P. Goff, unpublished data). Full-length
Abi-1 and
the deletion mutant proteins examined are depicted schematically
in
Fig.
2B. Surprisingly, the association of Abi-1 with Sos was
not
eliminated but instead was slightly enhanced by deletion of
the SH3
domain (Abi
394-475). Additional carboxy-terminal truncation
of
Abi-1 to amino acid 210 also failed to disrupt the interaction.
Further
deletion of amino acids 162 to 210, however, dramatically
reduced the
binding. In addition, Abi-1 mutant proteins lacking
amino acids 1 to 85 failed to interact with Sos. Thus, in contrast
to the results of
initial in vitro binding studies by our laboratory
and others
(
27) which detected a strong association between
the Abi-1
SH3 domain and Sos, this analysis indicates that amino-terminal
regions
of Abi-1 are more important than the SH3 domain for binding
to Sos in
mammalian cells. These results, however, do not rule
out the
possibility that the SH3 domain of Abi-1 also interacts
with Sos in
vivo. It is unclear whether the two amino-terminal
regions of Abi-1
required for binding, amino acids 1 to 85 and
162 to 210, are each
sufficient independently to mediate this
interaction.
We also investigated whether the binding of Abi-1 to Eps8 is necessary
for the interaction between Abi-1 and Sos. As shown
in Fig.
2C, the
interaction was not disrupted by deletion of a
proline-rich region
(Abi
304-401) that includes the Eps8-binding
site. This result
indicates that binding to Eps8 is not required
for the interaction
between Abi-1 and
Sos.
Association of Abi-1 and Grb2 in vivo.
One possible
consequence of the association between Abi-1 and Sos might be the
exclusion of other Sos interaction partners such as Grb2. We tested
whether overexpression of HA-Abi-1 can disrupt the ability of
cotransfected HA-Sos1 to coimmunoprecipitate with endogenous Grb2.
Plasmids encoding HA-tagged Abi-1 and HA-tagged Sos1 were cotransfected
into COS cells. Cell extracts were incubated with anti-Grb2 antibody,
and the immunoprecipitates were subjected to Western blot analysis with
anti-HA antibody. Overexpression of HA-Abi-1 did not alter the amount
of HA-Sos1 that coimmunoprecipitated with endogenous Grb2 compared to
that coimmunoprecipitated with the empty vector control (Fig.
3A). Overexpression of HA-Abi1-85 or
HA-Abi402-475 also failed to disrupt the interaction. In contrast, overexpression of HA-Sos2(874-1297) abolished binding of HA-Sos1 to
Grb2. In addition, cotransfection of myc-tagged Abi-1 with HA-Sos1 did
not perturb the association of HA-Sos1 with endogenous Grb2 (data not
shown). These data suggest that binding of Abi-1 to Sos does not
disrupt Grb2-Sos complexes.
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FIG. 3.
Association of Abi-1 and Grb2 in COS cells. (A) COS
cells were transiently cotransfected with the indicated HA-Sos1 and
HA-Abi-1 plasmids. Grb2 was immunoprecipitated from cell lysates.
Precipitated proteins (top) and total cell lysates (bottom) were
immunoblotted with anti-HA antibody (HA). The membrane from the top
blot was reprobed with anti-Grb2 antibody to confirm equal levels of
protein loading (middle). IP, immunoprecipitate; WB, Western blot. (B)
COS cells were transiently cotransfected with the indicated HA-Sos1 and
HA-Abi-1 plasmids. Serum-starved cells were left untreated or were
stimulated with EGF (100 ng/ml) for 2 or 10 min. Cell lysates were
prepared and incubated with anti-EGFR antibody. Precipitated proteins
(top) and total cell lysates (bottom) were immunoblotted with anti-HA
antibody. The membrane from the top blot was reprobed with anti-EGFR
antibody to confirm equal levels of protein loading. FL, full-length.
(C) COS cells were transiently transfected with the indicated
myc-Abi-1 plasmids. Grb2 was immunoprecipitated from cell lysates.
Precipitated proteins (top) and total cell lysates (bottom) were
immunoblotted with anti-myc antibody. The membrane from the top blot
was reprobed with anti-Grb2 antibody to confirm equal levels of protein
loading (middle).
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We also tested whether overexpression of Abi-1 can block recruitment of
Sos to activated EGFRs. Plasmids encoding HA-tagged
Abi-1 and HA-tagged
Sos1 were cotransfected into COS cells. Serum-starved
cells were left
untreated or were stimulated with EGF (100 ng/ml)
for 2 or 10 min. Cell
extracts were then incubated with anti-EGFR
antibody, and the
immunoprecipitates were subjected to Western
blot analysis with anti-HA
antibody. Stimulation with EGF for
2 or 10 min increased the amount of
HA-Sos1 that coimmunoprecipitated
with endogenous EGFR (Fig.
3B).
Compared to the empty vector control,
none of the HA-Abi-1 constructs
disrupted binding of HA-Sos1 to
EGFR in untreated or stimulated cells.
In contrast, coimmunoprecipitation
of HA-Sos1 with EGFR was
significantly reduced by overexpression
of HA-Sos2(874-1297). It
should be noted that this effect was
observed even though the level of
expression of HA-Sos2(874-1297)
relative to that of HA-Abi-1 was
severalfold
lower.
The above results indicate that overexpression of Abi-1 does not
disrupt Grb2-Sos complexes or their recruitment to activated
EGF
receptors. These findings also suggest the possibility that
Abi-1, Sos,
and Grb2 can coexist in a single complex. Consistent
with this idea, we
found that myc-tagged Abi-1 can coimmunoprecipitate
with endogenous
Grb2 (Fig.
3C). The N-terminal 210 amino acids
of Abi-1 that were
sufficient for binding to Sos were also capable
of mediating the
interaction with Grb2. Thus, the amino terminus
of Abi-1 can either
directly or indirectly mediate binding to
both Sos and Grb2. Our
results to date, however, do not distinguish
between simultaneous or
mutually exclusive binding of Sos and
Grb2 to Abi-1. It is also unclear
at this time whether either
Sos or Grb2 is required for bridging of
Abi-1 to the other protein
in
vivo.
Inhibition of EGF-induced Erk2 activation by overexpression of
Abi-1.
To determine the functional significance of the interaction
between Abi-1 and Sos, we investigated the role of Abi-1 in
Sos-dependent signal transduction. We assayed the effect of
overexpression of Abi-1 on two EGF-induced signaling events downstream
of Sos and Ras, namely, the activation of Erk2 and JNK (14).
In addition, we assayed the effect of Abi-1 overexpression on
EGF-induced activation of Akt. Activation of Akt by EGF is PI3K
dependent, but the importance of Ras in this pathway is unclear
(3, 10). In the Erk2 assay, plasmids encoding myc-tagged
Abi-1 and HA-tagged Erk2 were cotransfected into COS cells.
Serum-starved cells were left untreated or were stimulated with EGF for
the times indicated in Fig.
4. To
determine the effect of Abi-1 overexpression on EGF-induced Erk2
activation, HA-Erk2 was immunoprecipitated from cell lysates and then
subjected to Western blot analysis with phospho-specific antibodies
that recognize only the active forms of Erk1 and Erk2. As expected, treatment of serum-starved cells with EGF for 5 min strongly
upregulated the amount of active HA-Erk2 (Fig. 4A). Significantly, both
basal and EGF-induced HA-Erk2 activities were inhibited in cells
expressing full-length Abi-1 compared to the levels in cells
transfected with the empty vector control. This inhibition was not
observed with either Abi1-85 or Abi394-475. Interestingly, a
time course analysis between 0 and 20 min of EGF stimulation revealed a
delay in HA-Erk2 activation in cells transfected with full-length Abi-1 as opposed to that in cells transfected with the empty vector control
(Fig. 4B, upper blots). In addition, overexpression of full-length
Abi-1 appeared to reduce Erk activity measured after 40 and 60 min of
EGF stimulation (Fig. 4C). While the effect of Abi-1 overexpression on
Erk activation at intermediate time points (10 or 20 min) was slightly
variable, we consistently observed a delay at early time points (1 and
2 min) and inhibition at late time points (40 and 60 min). In contrast,
cells transfected with either Abi394-475 or Abi1-85 exhibited
less delay in Erk activation and no reduction of Erk activity after 40 and 60 min of EGF stimulation (Fig. 4B, lower blots, C and data not
shown). These results suggest that full delay and inhibition of
EGF-induced Erk2 activation by Abi-1 requires both the interaction
between Abi-1 and Sos and the presence of an intact Abi-1 SH3 domain.
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FIG. 4.
Inhibition by Abi-1 of EGF-induced Erk2 activation but
not EGF-induced JNK or Akt activation. (A) COS cells were transiently
cotransfected with the indicated HA-Erk2 and myc-Abi-1 plasmids.
Serum-starved cells were left untreated or were stimulated with EGF
(100 ng/ml) for 5 min. HA-Erk2 was immunoprecipitated from cell lysates
with anti-HA antibody (HA) and immunoblotted with antibodies against
active Erks (top). The membrane was reprobed with anti-HA antibody to
confirm equal levels of protein loading (middle). Total cell lysates
were probed with anti-myc antibody to confirm expression of myc-tagged
Abi-1 proteins (bottom). FL, full length; IP, immunoprecipitate; WB,
Western blot. (B) The experiment whose results are shown here was
performed with the indicated plasmids as described for panel A except
that EGF treatment was for 1, 2, 5, 10, or 20 min. The relative
normalized amount of active Erk is shown beneath each lane. Graphic
plots of relative amounts of active Erk versus time are included for
both the upper and lower blots. (C) The experiment whose results are
shown here was performed with the indicated plasmids as described for
panel A except that EGF treatment was for 20, 40, or 60 min. The
relative normalized amount of active Erk is shown beneath each lane.
(D) The experiment whose results are shown here was performed as
described for panel A except that HA-JNK and antibodies against active
JNK replaced HA-Erk2 and antibodies against active Erks, respectively.
(E) The experiment whose results are shown here was performed as
described for panel A except that HA-Akt and antibodies against active
Akt replaced HA-Erk2 and antibodies against active Erks,
respectively.
|
|
In similar experiments, we tested the effect of Abi-1 overexpression on
EGF-induced HA-JNK and HA-Akt1 activation. As expected,
treatment of
serum-starved cells with EGF for 5 min increased
the amounts of active
HA-JNK and HA-Akt (Fig.
4D and E). Relative
to levels induced with the
empty vector control, none of the Abi-1
constructs altered either basal
or EGF-induced levels of HA-JNK
and HA-Akt activation. No increases or
decreases of EGF-induced
JNK or Akt activation by overexpression of
Abi-1 were revealed
by time course analyses (data not shown). These
results indicate
that the inhibition of EGF-induced Erk2 activation by
Abi-1 is
specific to the Erk
pathway.
Inhibition of v-Abl-induced Erk2 activation by overexpression of
Abi-1.
Transformation by v-Abl has been shown to require activated
Ras (26). We have previously found that overexpression of
either full-length Abi-1 or Abi1-85 can inhibit transformation by
v-Abl (28; A. Ikeguchi and S. P. Goff,
unpublished data). Taken together, these findings raise the
possibility that overexpression of Abi-1 inhibits v-Abl-mediated
transformation by blocking Ras-dependent signaling events.
Therefore, we investigated whether overexpression of Abi-1 can block
v-Abl-induced Erk2 activation. 293T cells instead of COS cells were
used for this experiment because the levels of v-Abl expression and
v-Abl-induced Erk activation were severalfold lower in COS cells than
those in 293T cells. 293T cells were cotransfected with plasmids
encoding HA-Abi-1, HA-Erk2, and either v-Abl or v-Src. Cell lysates
were prepared and probed with antibodies against active Erks. As shown
in Fig. 5, wild-type v-Abl strongly
induced Erk2 activation compared to the level induced by a mutant v-Abl lacking kinase activity. Overexpression of full-length Abi-1 completely abolished v-Abl-induced Erk2 activation. This inhibition of Erk2 activation occurred with no significant change in the levels of v-Abl
protein; thus, full-length Abi-1 mediated a strong reduction in the
specific activity of v-Abl for Erk signaling. Overexpression of
Abi1-85, which binds to Abl but not to Sos, also inhibited v-Abl-induced Erk activation but to a lesser extent than full-length Abi-1. It should be noted that in comparison to cells coexpressing full-length Abi-1 and v-Abl, cells coexpressing Abi1-85 and v-Abl show markedly decreased expression of v-Abl. This phenomenon has been
observed repeatedly and most likely contributes to reduced Erk
activation. Thus, although Abi1-85 did show significant inhibition of Erk2 activation, it did so primarily by a mechanism distinct from
that used by the full-length protein. The residual Erk2 activation, when normalized to the low levels of v-Abl remaining, indicates a
minimal effect of Abi1-85 on the specific activity of v-Abl for Erk
signaling. The effect of overexpression of the non-v-Abl-binding mutant
Abi394-475 on v-Abl-induced Erk2 activation could not be evaluated
due to nearly undetectable levels of this mutant Abi protein when
coexpressed with v-Abl (data not shown). However, Erk2 activation
induced by v-Src, which does not bind Abi-1, was largely unaffected by
overexpression of Abi-1 (Fig. 5). Thus, the binding of Abi-1 to Sos is
not sufficient to block Erk activation by all mitogenic stimuli.
Western blot analysis showed that the levels of HA-Abi-1 expression,
HA-Erk2 expression, and HA-Erk2 activation in cells expressing these
tyrosine kinases were similar. In summary, overexpression of Abi-1 can
inhibit Erk2 activation induced by both EGF and v-Abl. In both cases,
the maximal inhibitory effect requires amino acids 1 to 85 of Abi-1, a
region also required for the interaction with Sos. Our results also
suggest the possibility of distinct mechanisms of inhibition of
v-Abl-transforming activity for full-length Abi-1 and Abi1-85.
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FIG. 5.
Inhibition of v-Abl-induced Erk2 activation by Abi-1.
293T cells were transiently cotransfected with plasmids encoding
HA-Erk2, wild-type (WT) p160v-abl, kinase-dead
(KD) p160v-abl, or v-Src, and full-length
HA-Abi-1 (FL) or HA-Abi1-85 (1-85). Transfected cells were
serum starved in 0.2% FBS for 24 h before lysis. Cell lysates
were probed with antibodies against active Erks (Active Erk) (top),
HA (middle), and Abl (bottom). Expression of v-Src was not detected by
our methods. WB, Western blot.
|
|
Tyrosine phosphorylation of endogenous Abi-1 induced by v-Abl.
Abi-1 and v-Abl were previously shown to interact in vivo
(28). In addition, earlier results demonstrated that v-Abl
can phosphorylate Abi-1 in vitro. To determine whether v-Abl kinase activity can lead to tyrosine phosphorylation of endogenous Abi-1, we
took advantage of the D5 cell line, an NIH 3T3 subclone transformed with a temperature-sensitive mutant v-Abl (24). The v-Abl
kinase in D5 cells is inactive at 39°C, but kinase activity is
restored upon shifting cells to 32°C. We investigated whether
shifting D5 cells from the restrictive to the permissive temperature
could increase tyrosine phosphorylation of endogenous Abi-1. Abi-1 was immunoprecipitated from serum-starved D5 cells that were maintained at
39°C or were shifted from 39 to 32°C for 1 h. Precipitated proteins were immunoblotted with antiphosphotyrosine antibody. As shown
in Fig. 6A, the phosphotyrosine content
of Abi-1 was increased after shifting D5 cells to the permissive
temperature. In addition, the mobility of Abi-1 in gel electrophoresis
was reduced after the temperature shift, consistent with
postranslational modifications such as phosphorylation. Since the
ability of the anti-Abi-1 antibodies to immunoprecipitate endogenous
Abi-1 had not been previously characterized, we included controls to
confirm this result. Preimmune serum was unable to immunoprecipitate
putative Abi-1. In addition, preadsorption of anti-Abi-1 antibodies
with bacterial lysate containing glutathione S-transferase
(GST)-Abi-1 abolished recognition of this protein. Preadsorption of
anti-Abi-1 antibodies with bacterial lysate containing GST alone did
not block immunoprecipitation of putative Abi-1. These controls
indicate that the anti-Abi-1 antibodies can specifically recognize
endogenous Abi-1. It should be noted, however, that we have not ruled
out the possibility of cross-reactivity against Abi-2. In addition, the
apparent increase in Abi-1 detected after preadsorption with bacterial
lysates is due to cross-reactivity against comigrating bacterial
proteins (Fig. 6A and data not shown).
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FIG. 6.
Tyrosine phosphorylation of endogenous Abi-1 induced by
v-Abl. (A) Serum-starved D5 cells were left at 39°C (nonpermissive
temperature) or shifted to 32°C (permissive temperature) for 1 h. Abi-1 was immunoprecipitated from cell lysates and immunoblotted
with antiphosphotyrosine antibody (Ptyr) (top). The membranes were
reprobed with anti-Abi-1 antibodies to confirm equal levels of protein
loading (bottom). The arrows indicate the position of Abi-1. N and P
denote nonpermissive and permissive temperatures, respectively. WB,
Western blot. (B) Growth factor-deprived parental BAF/3 cells and BAF/3
cells stably transfected with p160v-abl were
left untreated or were stimulated with IL-3 (50 ng/ml). Abi-1 was
immunoprecipitated and immunoblotted as described for panel A. IP,
immunoprecipitate.
|
|
We also examined the phosphotyrosine content of endogenous Abi-1 in
cells that stably express wild-type v-Abl. The phosphotyrosine
content
of endogenous Abi-1 is dramatically increased in BAF/3
cells stably
transfected with p160
v-abl compared to that in
parental BAF/3 cells (Fig.
6B). Stimulation
of parental BAF/3 cells
with IL-3, however, did not result in
increased tyrosine
phosphorylation of Abi-1. Taken together, our
data demonstrate that
v-Abl kinase activity can lead to tyrosine
phosphorylation of
endogenous Abi-1.
Tyrosine phosphorylation of endogenous Abi-1 induced by serum
stimulation.
We next examined whether serum stimulation of
fibroblasts could also induce tyrosine phosphorylation of endogenous
Abi-1. Serum-starved BALB/c3T3 cells were left untreated or were
stimulated with 20% FBS for 10 or 30 min. Abi-1 was immunoprecipitated
from cell lysates and immunoblotted with antiphosphotyrosine antibody. As shown in Fig. 7, serum stimulation
induced tyrosine phosphorylation of Abi-1 within 10 min. The levels of
tyrosine phosphorylation were similar after 10 or 30 min of serum
stimulation. These results show that serum stimulation as well as v-Abl
kinase activity can result in tyrosine phosphorylation of
endogenous Abi-1.
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FIG. 7.
Tyrosine phosphorylation of endogenous Abi-1 induced by
serum stimulation. Serum-starved BALB/c3T3 cells were stimulated with
20% FBS for the indicated times (in minutes). Abi-1 was
immunoprecipitated from cell lysates with anti-Abi-1 antibodies
(Abi) and immunoblotted with antiphosphotyrosine antibody (top). The
membrane was reprobed with anti-Abi-1 antibodies to confirm equal
levels of protein loading (bottom). The arrows indicate the position of
Abi-1. PI, preimmune serum control; IP, immunoprecipitate; WB, Western
blot.
|
|
| |
DISCUSSION |
Our search for potential regulators or targets of Abi-1 functions
has identified Sos as a novel interaction partner of Abi-1. The
association between Abi-1 and Sos has been demonstrated both in vitro
and in vivo. Our results indicate that overexpression of Abi-1 can
inhibit the Erk pathway. We have mapped an indispensable Sos
interaction domain in vivo to the amino terminus of Abi-1 and have
shown that this region is required for the maximal inhibitory effect of
Abi-1 overexpression of EGF- and v-Abl-induced Erk2 activation. In
contrast to in vitro binding experiments performed by our laboratory
and others (27), the SH3 domain of Abi-1 is not necessary in
vivo for interaction with Sos. The SH3 domain is, however, required for
full inhibition of EGF-induced Erk2 activation.
During the preparation of this paper, Scita et al. reported genetic
evidence that Eps8 participates in signal transduction between Ras and
Rac (27). Those authors also provided biochemical data
supporting a role for a ternary complex of Eps8, Abi-1, and Sos in
generating Rac-specific GEF activity. Previous work had identified a
Rac-specific GEF activity of Sos and suggested that Ras-mediated PI3K
signaling through Sos might couple Ras and Rac activation
(16). A study using overexpression and immunodepletion of
Abi-1 and Eps8 suggests a positive role for Abi-1 in linking Ras to Rac
(27). Interestingly, others have shown that v-Abl-mediated induction of Erk activity can occur by Raf-independent (32) and Rac-dependent (25) pathways. However, it is unlikely
that inhibition of EGF-induced Erk activation by overexpression of Abi-1 is due to inhibition of Rac activity. Although our results confirm the physical interaction between Abi-1 and Sos, we did not
observe any effect of Abi-1 overexpression on EGF-induced activation of
JNK and Akt downstream of Rac and PI3K, respectively. In our
experiments, however, we overexpressed Abi-1 alone and not in
conjunction with Eps8. In addition, antibodies used to immunodeplete
Abi-1 might cross-react with other Abi family members that exhibit
different cellular activities. It is possible that the overall effect
on signaling components downstream of Ras is highly sensitive to the
relative stoichiometries of Abi family members and their interaction
partners, such as Eps8.
Regulation of the interactions of Abi-1 with its various binding
partners is likely to be complex. First, phosphorylation of Abi-1
appears to be regulated during the cell cycle and can alter the
association of Abi-1 with Eps8 (2). Hyperphosphorylated forms of Abi-1 fail to coimmunoprecipitate with Eps8. Recently, the SH3
domain of Eps8 has been shown to bind a novel PXXDY consensus sequence
found in Abi-1 and other Eps8 interaction partners (15). Therefore, it is possible that phosphorylation of the tyrosine residue
might regulate binding of the Eps8 SH3 domain to this motif. Notably,
we have observed tyrosine phosphorylation of endogenous Abi-1 in
response to both v-Abl kinase activation and serum stimulation. Second,
the Abi-1 mRNA is subject to alternative splicing, yielding protein
isoforms that can retain different sets of proline-rich motifs
(36). The differential expression of proline-rich motifs may
modulate the binding preferences and biological activities of Abi-1.
For example, alternative splicing of the neuronal signaling adapter
protein NUMB generates two types of isoforms with either a short or
long proline-rich region. These two types of NUMB isoforms have
distinct developmental functions (31). Third, we have
recently found that Abi-1 can oligomerize (data not shown). Both the
oligomerization and Sos interaction domains map to the amino terminus
of Abi-1, suggesting possible interplay between homomeric and
heteromeric interactions of Abi-1. There are examples of this interplay
among SH3-containing proteins. The SH3 domain of Eps8 exists in
monomeric and dimeric forms but binds to Abi-1 only as a monomer
(15). In addition, a recent report indicates that the
binding of SH3-containing amphiphysins to dynamin, a GTPase involved in
endocytic membrane trafficking, can prevent dynamin self-assembly into
oligomeric ring-shaped structures (17). Finally, binding of
an interaction partner to Abi-1 might promote or disrupt other
heteromeric interactions. Our results suggest that the amino terminus
of Abi-1 interacts with both Sos and Grb2. Therefore, it is possible
that the amino-terminal and SH3 domains of Abi-1 can bind
simultaneously to Sos or Grb2 and Abl, respectively. However, it is not
yet known whether the interaction of Abi-1 with Sos or Grb2 affects the
binding of Abi-1 to Abl proteins.
Our observation that overexpression of Abi-1 results in inhibition and
delay of EGF-induced Erk activation suggests a role for Abi-1 in
temporal regulation of Erk activity. The timing of Erk activation
within the cell can be critical in determining the biological response
to growth factor stimulation. For example, in PC12 cells, sustained
activation of Erks is required for neuronal differentiation in response
to nerve growth factor (NGF) (13). In contrast, transient
activation of Erks in response to EGF treatment of the same cells
elicits a proliferative response. It has been proposed that the
Ras-related GTPase Rap1 mediates the persistent activation of Erks
induced by NGF (35). It is possible that Abi-1 interacts
with Rap1-specific GEFs to regulate Rap1 and the duration of Erk
activation. However, this role for Rap1 in Erk activation has recently
been challenged (37). It is also possible that Abi-1 might
interact with other GEFs belonging to the Dbl family. The Dbl family
member Lfc localizes to microtubules, and overexpression of Lfc in NIH
3T3 cells induces formation of actin stress fibers and membrane ruffles
(11). Staining of Abi-1 overexpressed in NIH 3T3 cells
reveals a distinct filamentous pattern within the cytoplasm, consistent
with a role for Abi-1 in cytoskeletal reorganization (data not shown).
Therefore, Abi family members might interact with GEFs associated with
the cytoskeleton during cellular responses to growth factor stimulation.
In addition to finding a novel protein-protein interaction of Abi-1,
our work identifies a specific mitogenic pathway potentially regulated
by Abi proteins. The inhibition of EGF-induced Erk2 activation by
overexpression of Abi-1 is consistent with the hypothesized role of Abi
proteins as negative regulators of cell growth. Overexpression of Abi-1
also blocked v-Abl-induced Erk2 activation, providing a possible
explanation for the previously observed antagonistic role of
overexpressed full-length Abi-1 in v-Abl-mediated transformation (A. Ikeguchi and S. P. Goff, unpublished data). Since Abi proteins do
not appear to directly inhibit Abl kinase activity (28, 33), it has been proposed that their binding to v-Abl blocks access to
critical regulators or effectors of v-Abl function. For example, interaction with Abi proteins might preclude association of v-Abl with
Shc, Grb2, Crk, or Nck adapter proteins that can potentially couple Abl
to Sos, Ras, and the Erk pathway. Consistent with this idea, in vitro
binding experiments suggest that Grb2, Nck, and Abi-2 can bind to the
same proline-rich motif in Abl (5, 23). Furthermore, the
binding of Abi-1 to Sos alone is apparently not sufficient to block all
signaling to Erks; for example, overexpression of Abi-1 fails to
abolish v-Src-induced Erk activation. Alternatively, Abi proteins in
other contexts may utilize different mechanisms to modulate signal
transduction. For example, overexpression of Abi1-85, which still
binds to v-Abl but not to Sos, causes a strong downregulation of v-Abl
protein levels in our transient-cotransfection experiments. The
requirement for Abi proteins to disrupt recruitment of adapter proteins
or alter expression of v-Abl in the inhibition of oncogenic
transformation by Abelson murine leukemia virus remains to be investigated.
We cannot rule out the possibility that, at physiological levels, Abi-1
may participate in a positive way in transducing signals initiated by
v-Abl or EGF. Experiments with Drosophila suggest that both
fly and human Abi can enhance the ability of Abl to phosphorylate one
of its substrates, Ena, consistent with a positive role for Abi in this
pathway (12). In addition to recruitment of proteins through
its SH3 domain and proline-rich motifs, tyrosine phosphorylation of
Abi-1 might create docking sites for SH2-containing signaling proteins.
Thus, overexpression of Abi-1 in our system may simply uncouple key
signaling components. Nevertheless, it is intriguing to consider that
oncogenic forms of Abl and Src trigger the ubiquitin-dependent
proteolysis of Abi proteins (6). Therefore, it is possible
that oncogenic forms of Abl and Src circumvent the potential inhibitory
activities of Abi proteins by targeting these molecules for degradation.
| |
ACKNOWLEDGMENTS |
We thank K. Calame, T. Franke, A. Minden, P. Rothman, and J. Wang
for various plasmids and cell lines. We thank F. Cong, H. Yang, and A. Ikeguchi for construction of several plasmids. We thank M. Dorsch and
P. Rothman for critical reading of the manuscript and helpful discussion.
This work was supported by Public Health Service grant P01 CA 75399 from the National Cancer Institute. Support was also provided by the
National Institutes of Health grant MSTP 5T35HL07616. S.P.G. is an
investigator of the Howard Hughes Medical Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: HHSC Room 1127, Columbia University College of Physicians & Surgeons, 701 West 168th St., New York, NY 10032. Phone: (212) 305-3794. Fax: (212) 305-8692. E-mail: goff{at}cuccfa.columbia.edu.
| |
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Molecular and Cellular Biology, October 2000, p. 7591-7601, Vol. 20, No. 20
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
