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Molecular and Cellular Biology, March 2001, p. 1540-1551, Vol. 21, No. 5
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.5.1540-1551.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Grb2 and Shc Adapter Proteins Play Distinct Roles in Neu
(ErbB-2)-Induced Mammary Tumorigenesis: Implications for Human
Breast Cancer
David
Dankort,1,2,
Bart
Maslikowski,1
Neil
Warner,1
Nubufumi
Kanno,3
Harold
Kim,4
Zhixiang
Wang,5
Michael F.
Moran,6
Robert G.
Oshima,3
Robert D.
Cardiff,6 and
William
J.
Muller1,4,7,*
Departments of
Biology,1 Pathology and Molecular
Medicine,7 and Medical
Sciences,4 Institute for Molecular Biology and
Biotechnology, McMaster University, Hamilton, Ontario, Canada L8S 4K1;
Center for Comparative Medicine, University of California,
Davis, Davis, California 956162; The
Burnham Institute, La Jolla, California, 920373;
Department of Anatomy, University of Alberta, Edmonton,
Alberta, Canada T6G 2M75; and Banting and
Best Department of Research and Department of Molecular and
Medical Genetics, University of Toronto, Toronto, Ontario, Canada
M5G 1L66
Received 28 July 2000/Returned for modification 13 September
2000/Accepted 1 December 2000
 |
ABSTRACT |
Amplification of the Neu (ErbB-2 or HER-2) receptor tyrosine kinase
occurs in 20 to 30% of human mammary carcinomas, correlating with
a poor clinical prognosis. We have previously demonstrated that four
(Y1144 Y1201, Y1227 and Y1253) of the five known Neu autophosphorylation sites can independently mediate transforming signals. The transforming potential of two of these mutants correlates with their capacity to recruit Grb2 directly to Y1144 (YB) or indirectly through Shc to Y1227 (YD). Here, we demonstrate that these
transformation-competent neu mutants activate extracellular signal-regulated kinases and stimulate Ets-2-dependent
transcription. Although the transforming potential of three of these
mutants (YB, YD, and YE) was susceptible to inhibition by Rap1A, a
genetic antagonist of Ras, the transforming potential of YC was
resistant to inhibition by Rap1A. To further address the significance
of these ErbB-2-coupled signaling molecules in induction
of mammary cancers, transgenic mice expressing mutant Neu receptors
lacking the known autophosphorylation sites (NYPD) or those
coupled directly to either Grb2 (YB) or Shc (YD) adapter
molecules were derived. In contrast to the NYPD strains,
which developed focal mammary tumors after a long latency period with
low penetrance, all female mice derived from YB and YD strains rapidly
developed mammary tumors. Although female mice from several independent
YB or YD lines developed mammary tumors, the YB strains developed lung metastases at substantially higher rates than the YD strains. These
observations argue that Grb2 and Shc play important and distinct roles
in ErbB-2/Neu-induced mammary tumorigenesis and metastasis.
| |
INTRODUCTION |
Neu (ErbB-2), the epidermal
growth factor receptor, ErbB-3, and ErbB-4 are transmembrane
receptor tyrosine kinases (RTKs) which comprise the class I or ErbB RTK
family (reviewed in references 21, and 35).
Neu or ErbB-2 amplification and elevated expression has been implicated
in the etiology of human ovarian and breast cancers and correlates with
a poor clinical prognosis in breast cancer patients (3, 44,
45). Moreover, anti-ErbB-2 antibodies demonstrate efficacy for
treatment of breast cancer patients with elevated ErbB-2 levels
(4). Direct evidence supporting a role for neu
in mammary tumorigenesis derives from observations made with transgenic
mice expressing oncogenic forms of the neu oncogene under the transcriptional control of mouse mammary tumor
virus (MMTV) enhancer. Mammary epithelial cell-specific
expression of wild-type Neu or constitutively active Neu or ErbB-2
alleles in the mammary epithelia of transgenic mice results in the
induction of metastatic mammary tumors which histologically resemble
human comedocarcinomas (2, 6, 18, 19, 30). Taken together, these data suggest that activation of ErbB-2 or Neu plays a causal role
in mammary tumorigenesis.
Despite the importance of Neu in human malignancies, the molecular
mechanism by which this RTK transforms cells and confers metastatic
potential is not known. Following Neu receptor dimerization, class I RTKs become phosphorylated predominantly at discrete tyrosine residues within a 200 to 300-amino-acid carboxyl-terminal region. These phosphorylated tyrosines provide binding sites for a variety of cytoplasmic Src homology 2 (SH2) and/or protein tyrosine binding (PTB) domain-containing proteins involved in transducing
proliferative/transforming or differentiating signals to the nucleus.
SH2 and PTB domains directly interact with phosphotyrosyl proteins in a
sequence-specific manner (reviewed in reference 36),
thereby conferring specificity to RTK signaling.
Many reports have identified the signaling proteins which interact with
Neu, yet the role that each molecule plays in signal transduction is
less clear. A number of SH2 and PTB domain-containing proteins have
been implicated in Neu signaling; these intracellular signaling
molecules include phospholipase C
1 (PLC1), c-Src, Crk, Grb7, and
proteins which modulate Ras activity either by promoting active Ras-GTP
complex formation through Sos GDP/GTP exchange proteins (Grb2, Shc, and
Nck) or by accelerating the hydrolysis of Ras-GTP to its inactive
Ras-GDP state (Ras-GTPase-activating protein) (12, 13, 24, 27,
31-34, 37, 41, 46). While the binding sites on Neu for many of
these SH2 and PTB domain-containing proteins are unclear, deletion or
mutation of Neu tyrosine phosphorylation sites can dramatically affect
the transforming activity of Neu (1, 5, 9, 10, 39, 40).
There is little consensus as to the relative importance of these
tyrosine autophosphorylation sites, although it appears that no single
site is required to mediated transformation.
To systematically address the role of tyrosine phosphorylation sites in
Neu-mediated transformation, we used a strategy initially described for
the platelet-derived growth factor receptor (48). In this study, individual tyrosine residues were restored to a mitogenically inactive mutant platelet-derived growth factor
receptor containing tyrosine-to-phenylalanine changes at the known
tyrosine phosphorylation sites to create a series of phosphorylation
add-back mutants. To address the functional significance of specific
signaling molecules in Neu-mediated transformation, we have generated a similar series of mutant activated neu receptors that either
lack all known tyrosine autophosphorylation sites (Neu tyrosine
phosphorylation deficient [NYPD]) or possess only one of these sites
in isolation (add-back mutants NT-YA to -YE) (9). For
purposes of simplicity, we refer to each of these add-back mutants as
YA (tyrosine residue 1028), YB (tyrosine residue 1144), YC
(tyrosine residue 1201), YD (tyrosine residue 1227), and YE
(tyrosine residue 1253). In established fibroblasts, reconstitution
of single phosphorylation sites to NYPD, creating a series of
add-back mutants, reveals that four of five phosphorylation sites
(sites B through E) can independently mediate transforming signals,
whereas tyrosine 1028 (site A) functions to repress transforming
signals from the receptor (9). While Grb2 associates
directly with Y1144 (site B) and indirectly through
tyrosine-phosphorylated Shc proteins at Y1226/7 (site D), the
molecular basis for transformation activity from sites C (Y1201) and E
(Y1253) has yet to be elucidated.
Here we have assessed the importance of Ras signaling pathway in
mediating transforming activity of Neu add-back mutants YB, YC, YD, and
YE. The results revealed that coexpression of genetic antagonist of Ras
signaling, Rap1A, could effectively interfere with three of the four
add-back mutants (YB, YD, and YE) but was ineffective in inhibiting a
transforming signal from the YC mutant. Despite differences in the
response to Rap1A expression, all four transforming add-back mutants
were capable of activating the mitogen-activated protein (MAP) kinase
cascade and of inducing the transcription of an ets-2
reporter gene. Although Grb2 binds directly to the YB (Y1144)
phosphorylation site and indirectly to YD (Y1226/7) through the Shc
adapter protein, microinjection experiments reveal that unlike site B,
the Shc binding site does not require Grb2 activity to mediate DNA
synthesis. These observations suggest that although these Neu
autophosphorylation sites are functionally redundant in cellular
transformation, they use distinct signaling effector mechanisms to
activate Ets-2 and MAP kinase pathways.
To further explore the biological importance of Neu-coupled Shc and
Grb2 signaling in mammary tumorigenesis, we have generated transgenic
mice by activated neu alleles of NYPD, YB, and YD under the
transcriptional control of the MMTV long terminal repeat (LTR). Mammary
epithelial cell-specific expression of the YB and YD neu alleles resulted in the rapid induction of multifocal mammary tumors.
In contrast, expression of the NYPD mutant resulted the generation of
focal mammary tumors only after a long latency period. Although YB and
YD mutant alleles were capable of efficiently inducing mammary cancers,
the YB-induced tumors metastasized with much higher frequency than
YD-induced mammary tumors. Taken together, these observations suggest
that Grb2 and Shc have distinct biological effects on Neu-induced
mammary metastasis.
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MATERIALS AND METHODS |
Cell lines and transformation assays.
Rat1 fibroblasts and
293T epithelial cells were maintained in Dulbecco's modified Eagle
medium (DMEM) supplemented with 10% fetal bovine serum (FBS),
amphotericin B (Fungizone), and penicillin-streptomycin or gentamicin.
Contransfections in Fig. 1 were carried out using LipofectAmine reagent
(GibcoBRL). Rat1 fibroblasts were seeded at 3 × 105
cells in 35-mm-diameter tissue culture dishes following the
manufacturer's instructions with 100 ng of transforming plasmid or
vector and 1 µg of inhibitory plasmid (pKRev-1/Rap1A) or empty vector
(SV2Neo). At confluency, contents of the plates were split into two
60-mm-diameter plates, which were maintained in 4% FBS-supplemented
DMEM for 14 days, with a change of medium every third day. Plates were maintained in supplemented DMEM for 14 days, with a change of medium
every third day. Plates were stained with Giemsa stain, and the foci
were counted from six plates per construct. Relative transformation
potential was normalized to that obtained with activated Neu (NT) in
the presence of SV2Neo in each experiment multiplied by 100. EKOI
fibroblasts, established from Ets-2-deficient teratocarcinoma cells
(55), were maintained in DMEM supplemented with 10% fetal
calf serum.
Erk activation and Ets-2-dependent transcription in transient
transfections.
293T cells were seeded at 75% confluency in
60-mm-diameter tissue culture dishes in 10% FBS-supplemented DMEM and
transfected the following day with DNA-liposome complexes containing 12 µg of plasmid DNA and 48 µl of LipofectAmine reagent for 5 h.
Following 48 h, the medium was replaced with serum-free DMEM to
reduce background extracellular signal-regulated kinase (Erk)
phosphorylation, and cells were further incubated for 3 to 5 h
prior to lysis in hypotonic lysis buffer (20 Tris-HCl [pH 7.5], 2mM
EDTA, 2 mM EGTA, 10 mM NaF, 10 mM sodium pyrophosphate) supplemented
with 1 mM Na3VO4 and the protease inhibitors
aprotinin and leupeptin at 10 µg/ml. Following 20 min, NaCl was added
to 400 mM (final concentration), and the mixture was further incubated
for 20 min. Immunoblots containing 50 µg of total protein were
analyzed using antiphosphotyrosine (PY20), anti-Erk (C14; Santa Cruz
Biotechnology), or anti-phospho-Erk (New England Biolabs) antibodies.
E18 luciferase and FNEts2 and FNEts2 A72 expression plasmids were
provided by C. Hauser (14). EKO1 cells (8.0 × 104) were plated in 12-well dishes 24 hs prior to
transfection and then transfected by the calcium phosphate
coprecipitation method. The day after transfection, the medium was
changed to DMEM containing 0.5% fetal calf serum and incubated for an
additional 24 h before lysates were processed for luciferase and
-galactosidase activity.
Affinity purification, immunoprecipitation, and
immunoblotting.
Cells were washed twice in 1 × phosphate-buffered saline (PBS) at 4°C, and lysates were made in PLC
lysis buffer (50 mM HEPES [pH 7.5], 150 mM NaCl, 10% glycerol, 1%
Triton X-100, 1 mM EGTA, 1.5 mM MgCl2, 10 mM NaF, 10 mM
sodium pyrophosphate, 1 mM Na3VO4, 10 µg of
aprotinin/ml, 10 µg of leupeptin/ml). Tumors were ground to a powder
under liquid nitrogen, and lysates were made in PLC lysis buffer. Neu
was immunoprecipitated with protein G-conjugated monoclonal antibody
7.16.4. The immunoprecipitates were washed five to seven times in PLC
lysis buffer prior to immunoblot analyses with either anti-Neu (Ab3;
1:1,000; Oncogene Science) or anti-phosphotyrosine (PY20; Transduction
Laboratories) antibodies as described elsewhere (9). Grb2
(C23; 1:400; Santa Cruz) and Shc (S14630; 1:1,000; Transduction
Laboratories) were detected using rabbit polyclonal antibodies. The
peptides pYE (biotin-FEGTPTAENPE[pY]LGLDVPV) and pYC
(biotin-FAFGGAVENPE[pY]LVPREGT), synthesized by Research Genetics, were resuspended in 20 mM buffered HEPES and brought to pH 7.0. Peptides were incubated with or without calf intestinal alkaline phosphatase (60 U/µg) at 37°C for 2 h. Peptides were
immobilized to streptavidin-agarose, washed extensively in PLC lysis
buffer, and aliquoted such that each affinity purification mixture
contained 1 µg of immobilized peptide. Protein lysates (500 µg)
from Rat1 cells were incubated at 4°C with immobilized peptides on a
rotating platform for 1 h and washed four to six times in PLC
lysis buffer, and specific complexes were subjected to anti-Crk
immunoblot analysis.
GST fusion production and direct affinity assay.
Escherichia coli BL21 (Stratagene) was transformed with
pGSTag-derived glutathione S-transferase (GST), GST-PLC,
and GST-Crk plasmids, and glutathione fusion proteins were purified as
described elsewhere (9). Direct binding assays were
performed as follows: Serial dilutions (0.01 to 1 µg) of GST fusion
proteins were spotted onto nitrocellulose membranes and air dried.
Membranes were blocked in 0.3% gelatin in 0.1% Tris-buffered
saline-Tween (TBST-G) for 1 h. Membranes were then rinsed twice
with TBST and incubated with peptides (1 µg/ml) in TBST-G for 1 h at room temperature. Blots were washed thrice for 10 min with TBST
and incubated with a 1:2,500 dilution of 125I-streptavidin
(IM236; Amersham) in TBST-G for 1 h. Blots were washed again,
dried, and autoradiographed.
Grb2 inhibition of DNA synthesis.
DNA synthesis was assayed
after metabolic incorporation of 5-bromo-2'-deoxyuridine (BrdU) (cell
proliferation kit; Amersham) as described previously (9,
52). Cells growing on glass cover slips were deprived of serum
overnight (~18 h) and then noninjected or microinjected with 0.5 × PBS containing biotinylated Grb2 SH2 domain (2 mg/ml). After incubation
at 37°C for 2 h, fresh medium containing 10% FBS and BrdU was
added, and the coverslips were incubated at 37°C for 18 h. Following
fixation, BrdU incorporated into DNA was visualized with a BrdU
antibody and a rhodamine-labeled secondary antibody to mouse
immunoglobulin. Microinjected cells were identified by staining with
fluorescein isothiocyanate-labeled avidin (Jackson Immunology
Laboratory). Not less than 100 cells were injected on each coverslip,
and DNA synthesis was determined as the percentage of microinjected
cells staining positively for BrdU incorporation. Equivalent results
were obtained from two independent experiments, and results from one
such experiment are shown. In noninjected cells, the percentage of
BrdU-labeled cells was determined for not less than 200 cells counted
from randomly selected fields of view. Cells were visualized for
simultaneous red and green fluorescence by using the appropriate filter
sets (Carl Zeiss Ltd.).
Generation of transgenic mice, tumor kinetics, and histological
evaluation.
cDNAs corresponding to the autophosphorylation mutants
(NYPD, YB, and YD) containing an activating extracellular deletion (8142) (42) were excised from pJ4
HindIII-EcoRI fragments and inserted into the
corresponding sites of p206 under the transcriptional control of the
MMTV LTR followed by simian virus 40 (SV40) polyadenylation sequence.
Transgenic mice were generated by pronuclear injection of zygotes
obtained from FVB × N intercrosses as described elsewhere (43). All mice were obtained from Taconic Farms
(Germantown, Pa). Founder animals were identified by Southern blot
analyses using an SV40 poly(A)-specific 32P-labeled probe,
and progeny were routinely detected by PCR with transgene-specific
oligonucleotides. Nulliparous and multiparous female mice were
monitored for mammary tumor formation by physical palpation of the
mammary glands. Tumor kinetics were obtained from nulliparous animals
from MMTV/neundl-NYPD (line 10 [NYPD10]), -YB
(line 2 [YD2]), and -YD (line 5 [YD5]) strains. Whole-mount
preparations of the number 4 mammary gland was completed as described
elsewhere (50). Tissue was fixed in phosphate-buffered 4%
paraformaldehyde or formalin at 4°C, transferred to 70% ethanol, and
blocked in paraffin. Sections (4 µm) were stained with hematoxylin
and eosin (Anatomical Pathology, McMaster University). Lung metastases
were evaluated by microscopic analyses of lung sections.
| |
RESULTS |
Neu transforming activity functions through distinct
Rap1A-sensitive and -resistant pathways.
Our previous
observations have implicated the Ras signaling pathway in Neu-induced
DNA synthesis (9). To further assess the role of the Ras
signaling pathway in Neu-mediated transformation, we have coexpressed a
competitive inhibitor of Ras, known as Rap1A, with the various Neu
autophosphorylation mutants. Rap1A functions as a dominant Ras
inhibitor by titrating critical Ras substrates to an inactive Rap1A
-substrate (20, 38, 47) and has the ability to revert
v-Ki-ras-transformed cells when overexpressed (26). To accomplish this, we cotransfected Rap1A with
various Neu mutants into Rat1 fibroblasts and assessed transformation in focus formation assays. Expression of Rap1A induced a threefold reduction in NT transformation relative to empty vector, demonstrating a role for Ras in this process, but had little effect on NYPD transformation (Fig. 1A). Interestingly, Rap1A
similarly inhibited transformation from YB, YD, and YE, whereas YC
appeared to be largely Ras independent in this assay. The YA mutant was
not included in these analyses, since we have previously demonstrated
that this mutant is completely transformation defective
(9). The ability of Rap1A to interfere with the
transforming activity of these add-back mutants appeared to be specific
to Ras since Rap1A had little effect on the transforming activity of
SV40 large T antigen, (lt) which is known to transform cells in a
Ras-independent manner (25). These results demonstrate
that three of four transforming add-back mutants are susceptible to
this genetic inhibitor of Ras function.
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FIG. 1.
Ras is required for transformation from activated Neu
autophosphorylation mutants that stimulate Erk. (A) Ras requirements
for Neu add-back-mediated transformation. Activated Neu (NT) is
depicted with its tyrosine phosphorylation sites
( )
at residues 1028 (site A), 1144 (site B), 1201 (site C), 1226/7 (site
D), and 1253 (site E). NT-NYPD and the derived add-back mutants NT-YB
through NT-YE contain tyrosine to phenylalanine
( ) mutations at the indicated
tyrosine phosphorylation sites. Focus formation assays were carried out
in Rat1 fibroblasts transfected with plasmids encoding the indicated
Neu mutants or SV40 large T antigen along with either a control vector
(SV2Neo) or one encoding Rap1A. Transforming activity (± standard
error) was determined from triplicates in three experiments and is
expressed relative to NT with SV2Neo. (B to D) 293T cells were
transfected with pJ4-derived plasmids encoding Neu phosphorylation
mutants. Immunoblots (IB) containing 50 µg of total protein were
analyzed with anti-Neu (B) and phospho-Erk1/2 (p-Erk) (C) antibodies,
and the membrane in panel C was reprobed with Erk1/2-specific antisera
(D).
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Given that activation of Ras results in the initiation of a kinase
cascade terminating in the phosphorylation and activation
of Erks
(
29), we investigated whether Neu add-back mutants were
capable of stimulating Erk phosphorylation. To accomplish this,
we
transfected 293T cells with empty vector or those encoding
NT or the
derived mutants and assessed Erk phosphorylation with
anti-Erk
phosphospecific antisera (Fig.
1C). These analyses revealed
that NT and
each transforming add-back mutant activates Erks whereas
NYPD fails to
due so, despite expressing comparable amounts of
Neu (Fig.
1B). Thus,
activated Neu and the YB, YD, and YE add-back
mutants both activate Ras
signaling and display Ras-dependent
transforming activities, whereas YC
expression induces Erk phosphorylation
but is not inhibited by Rap1A
overexpression.
Another important indicator of Ras activity is its ability to activate
certain classes of transcription factors. Indeed, activated
Ras is
known to stimulate the transcriptional activity of the
Ets-2
transcription factor through the MAP kinase phosphorylation
of
threonine 72 in the Ets-2 pointed domain (
56). To explore
whether Ets-2-dependent transcription was differentially effected
by
the different Neu add-back mutants, the various Neu add-back
mutants
were cotransfected with an Ets-2-dependent luciferase
reporter (E18)
(
12) and expression vectors harboring either
wild-type
Ets-2 or mutant Ets-2 bearing an alanine substitution
for threonine 72 (Ets-2 A72) (Fig.
2). Cotransfection of
control
vector NYPD or YA mutants with the Ets-2 expression vector
resulted
in a modest twofold activation of the reporter construct. In
contrast,
cotransfection of NT, YB, YC, YD, and YE mutants resulted in
a
5- to 10-fold stimulation of Ets-2-dependent transcription (Fig.
2).
Stimulation of the Ets-2 reporter construct by these
neu
mutants
was dependent on the conservation of the Ets-2 MAP kinase
phosphorylation
site since cotransfection of the Ets-2 A72 mutant
failed to activate
the Ets-2 reporter construct. Taken together, these
observations
suggest that transformation-competent
neu
mutants funnel through
the MAP kinase signaling pathway and stimulate
Ets-2-dependent
transcription through the Ets-2 MAP kinase
phosphorylation site
(threonine 72).
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FIG. 2.
Neu mutants induce Ets-2 transcriptional
activation through threonine 72. The E18 luciferase reporter
construct was cotransfected into EKO1 Ets-2-deficient cells with the
various Neu add-back mutants, wild-type ets-2 expression
vector (FNEts2) (open box), or mutant ets-2 with alanine
substitution at threonine 72 (FNEts2 A72) (closed box). Also included
was a -actin-driven -galactosidase expression vector, which
served as an internal control for transfection efficiency. The ratio of
luciferase activity relative to that observed for the empty pJ4
expression vector was used to calculate fold activation.
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While all of the transforming
neu mutants were capable of
stimulating MAP kinase activity and activating Ets-2-dependent
transcription,
YC-mediated transformation remained refractory to Rap1A
inhibition
(Fig.
1A). One potential explanation for these observations
is
that the transforming signal from the YC mutant is not dependent
on
Ras activity. Indeed, it has recently been demonstrated that
the Crk1/2
adapter protein recruits the C3G exchange factor, which
in turn can
activate Erk kinases in a Ras-independent fashion
(
22,
23). To explore the possibility that site C interacts
with Crk,
we generated chemically synthesized phosphorylated and
nonphosphorylated peptides spanning site C from positions
11
to +7
relative to the phosphotyrosine residue. To control for
nonspecific
binding, we also included peptides directed to the
Rap1A-sensitive E
site. The amino terminus of each peptide was
covalently linked to
biotin, thus providing a means of immobilizing
the peptides via
streptavidin-conjugated agarose beads. To determine
whether Crk
interacted with site C, affinity purification assays
were carried out
with the immobilized peptides to site E or C
followed by immunoblot
analyses with Crk-specific antisera. The
results revealed that the site
C specifically associated with
Crk protein whereas the phosphorylated
site E peptide failed to
associate with Crk (compare lanes 3 and 5 in
Fig.
3A). In parallel
assays, we have
shown that the site E peptide is capable of associating
with a number
of unidentified cellular proteins. Furthermore,
Crk-specific binding is
dependent on phosphorylation of tyrosine
residues since
dephosphorylated site C peptide showed no evidence
of stable
association.
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FIG. 3.
Crk interacts with phosphopeptides containing tyrosine
1201 (site C) in vitro. (A) Immobilized phosphorylated and
unphosphorylated peptides (1 µg) were incubated with 500 µg of Rat1
fibroblast lysates. Associated proteins were electrophoresed on a
sodium dodecyl sulfate-12% polyacrylamide gel and subjected to
anti-Crk immunoblot analysis. The migration of Crk is indicated. (B)
Membrane-immobilized GST fusion proteins were incubated with
phosphorylated and unphosphorylated peptides (1 µg/ml). Membranes
were subsequently probed with 125I-streptavidin and
autoradiographed. Serial dilutions of fusion (0.01 to 1 µg) are
indicated.
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To assess whether the phosphorylated YC peptide could directly
associate with the SH2 domain of Crk, a direct binding assay
was
performed. Membrane-immobilized GST fusion proteins containing
the SH2
domain of Crk or PLC
were probed with either phosphorylated
peptides
made to site C or E or a control dephosphorylated C peptide.
The
results revealed that only the GST-Crk fusion protein could
directly
bind the phosphorylated YC peptide (Fig.
3B). Taken together,
these
results suggest that theRap1A refractory site C binds Crk
in a
phosphospecific manner in
vitro.
YB and YD mediate Grb2-dependent and -independent signals,
respectively.
Previous studies have indicated that YB and YD
mutants independently mediate transforming signals through their
ability to directly recruit Grb2 (YB) or indirectly sequester Grb2 via
its interaction with the Shc adapter protein (YD). The specificity of
binding partners for YB and YD was further confirmed by the creation of
secondary mutations in the consensus binding sites for Grb2 and
Shc adapter proteins, respectively (D. Dankort and W. J. Muller, unpublished observations). To determine the requirement for
Grb2 in mediating signals from Neu, we microinjected a dominant negative inhibitor of Grb2 into established cell lines expressing the
various add-back Neu mutants and assessed the ability of this Grb2
inhibitor to interfere with Neu-induced DNA synthesis. Because the
dominant negative inhibitor of Grb2 comprises only the Grb2-SH2 domain
fused to GST and lacks SH3 domains, it can compete with the endogenous
Grb2 for receptor binding but cannot couple to downstream Sos exchange
factors to activate the Ras signaling pathway (50).
Microinjection of the Grb2 SH2 domain into Rat1 fibroblasts expressing
NT (Fig.
4) had a minimal effect on the
capacity of
these cells to undergo DNA synthesis as assessed by BrdU
incorporation
(90% of uninjected controls), suggesting that there
exists at
least one Grb2-independent signal emanating from Neu.
Inhibition
of Grb2 function dramatically reduced DNA synthesis in NYPD
cells
and control Rat1 fibroblasts. The potent inhibition of these cell
lines likely reflects a dependence on serum factors for initiating
DNA
synthesis. In contrast, cell lines expressing YA, YC, and
YE were
largely Grb2 independent in these assays (80 to 90% of
noninjected
controls). Although Grb2 binds to both sites B and
D, microinjection of
the Grb2 inhibitor strongly suppressed YB-induced
DNA synthesis (13%
of uninjected controls) and had only marginal
effect on BrdU
incorporation in YD-expressing cells (72% of noninjected
controls)
(Fig.
4). These data are consistent with the view that
the primary
Grb2-dependent signal from Neu is mediated by the
YB phosphorylation
site.
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FIG. 4.
Effect of Grb2 SH2 domain microinjection on DNA
synthesis from add-back cell lines. Cells rendered quiescent through
serum deprivation were either uninjected (black bars) or microinjected
with 1 µg of biotinylated Grb2 SH2 domain (grey bars) and released
from quiescence via addition of serum, at which time BrdU added. The
percentages of BrdU-positive injected or noninjected cells are
graphically depicted. DNA synthesis was determined as the percentage of
microinjected cells (not less than 100 cells for each line) staining
positively for BrdU incorporation. Equivalent results were obtained
from two independent experiments, and results from one such experiment
are shown.
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Direct Grb2 recruitment by Neu is associated with a metastatic
tumor phenotype.
Although these observations suggest that
recruitment of Grb2 or Shc to Neu may result in the activation of
distinct effector pathways, the in vivo relevance of these Neu-coupled
pathways is unclear. Thus, we tested the effects of activation of these coupled signaling pathways in mammary tumorigenesis and metastasis by
targeting expression of NYPD, YB, and YD to the mammary epithelium of
transgenic mice. These different neu phosphorylation mutants were placed in the context of an activating extracellular deletion (NDL1) which efficiently induces metastatic mammary tumors in transgenic mice (43). While this deletion mutant
transforms at approximately 50% of the level of NT, the relative
transforming potential of the derived add-back mutants in culture
remains the same, suggesting that these mutants function similarly in a
different activating background (not shown).
Multiple independent MMTV/NYPD, MMTV/YB, and MMTV/YD
transgene lines were generated by pronuclear injection of fertilized
mouse zygotes. Expression of the transgene in derived mammary
RNA
samples was verified by reverse transcription-PCR (data not
shown). A
number of expressing founder animals did not pass the
transgene to
their progeny; thus, we restricted our subsequent
analyses to two
strains for each phosphorylation allele (NYPD10,
NYPD11, YB2, YB6, YD5,
and YD6). We performed whole-mount analyses
on virgin female mammary
glands to ascertain the phenotypic consequences
of expression of these
various
neu mutants. These analyses revealed
that
mammary expression of NYPD led to significant alveolar
development,
histologically resembling normal mammary epithelium
(Fig.
5A and
B). In contrast to this
relatively normal developmental profile,
the MMTV/YD-derived mammary
glands possessed dense hyperplastic
foci that were histologicaly
composed of solid glandular arrays
of epithelial cells (Fig.
5C and D).
MMTV/YB whole mounts display
histological abnormalities which include
ductal ectasia with scattered
foci of papillary epithelial hyperplasia
(Fig.
5E and F).
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|
FIG. 5.
Mammary gland architecture of MMTV/activated
neu mutants. Photoimages show whole-mount preparations (A,
C, and E) and comparable microscopic fields (B, D, and F) of mammary
glands of mice harboring NYPD10 (A and B), YD5 (C and D), and YB2 (E
and F) neu autophosphorylation mutants. All mammary glands
are from 12 to 14-week-old virgin female mice. Note that all mammary
whole mounts have some degree of alveolar development and foci of
intraluminal hyperplasia. The YB mutant mice had the most severe ductal
ectasia with scattered foci of papillary hyperplasia (E and F). The YD
mutant strain had less ductal ectasia, but the hyperplastic lesions
were composed of solid glandular arrays (C and D). The NYPD mutant had
significant lobular development that tended to follow normal
histological patterns (A and B). (Normal mammary gland morphologies for
the FVB strain can be viewed online
[http://ccm.ucdavis.edu/tgmouse/wmtable.htm].) The size bars in
panels E and F indicate 1 and 0.1 mm, respectively.
|
|
Given the observed abnormal development with the various mutant
neu strains, we monitored cohorts of virgin female mice from
representative NYPD (NYPD10) YB (YB2), and YD (YD5) strains for
the
development of mammary tumors. Mammary epithelial expression
of
activated YB and YD alleles efficiently induced mammary tumors
at rates
comparable to those for other MMTV-driven activated alleles
(
30,
43) (Fig.
6A). While female YB or
YD
neu transgenic mice
both developed mammary tumors with
complete penetrance at average
age of onset of 152 and 102 days,
respectively (Fig.
6A; Table
1), the
mammary tumors that arose in the YD strains tended to
be multifocal in
origin (>10 tumors per mouse) whereas those of
the YB strains
generally were focal in nature. In contrast, focal
mammary tumors arose
only after a long latency period in the NYPD
females (Fig.
6A, average
age of onset= 252 days), and tumors
arose with a penetrance of either
13 or 50%, depending on the
line, after a 1-year observation period
(Table
1). Limited analyses
of independent NYPD, YB, and YD transgenic
strains (NYPD11, YB6,
and YD6) revealed similar times of tumor onset
and phenotypes
(Table
1), suggesting that observed characteristics of
these
strains were independent of integration site.
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FIG. 6.
Mammary tumorigenesis and metastasis in transgenic mice
expressing neu autophosphorylation mutants. (A) Mammary
tumor kinetics in YB 2, YD 5, and NYPD 10 mice. Age indicated is that
(days) at which a mammary tumor was first palpable in each transgenic
strain. The number of female animals analyzed for each strain
(n) and median age at which tumors are palpable
(t50) are also shown. The mean tumor latencies
for YB and YD are statistically different (P = 0.002, Students t test). (B) Percentage of tumor-bearing animals
with metastatic lesions in the lung. The percentage of all
tumor-bearing mice harboring lung metastases is indicated for each
genotype; the number of animals analyzed is indicated (n).
While there are no statistically significant differences between
occurrence of lung metastastes in NYPD and YD animals, Fisher exact
tests demonstrate significant differences between occurrence of
metastases in YB versus NYPD (*, P = 0.012) and YD (**, P = 0.0002) mice.
|
|
Although expression of the YB and YD transgenes was capable of
efficiently inducing mammary tumors, there were marked differences
of
the histopathology of these tumors. YD transgene expression
was
primarily associated with the induction of solid comedo-type
tumors
reminiscent of tumors induced by activated
neu (Fig.
7C),
while the YB-induced mammary tumors
were comprised of papillary
fronds (Fig.
7D). The tumors induced by
mammary epithelial expression
of NYPD also resembled the parental
activated
neu-induced tumors
(Fig.
7A and B). In addition to
the striking morphological differences
between the various
neu mutants, these strains differed markedly
in the relative
rates of metastatic progression observed. Overall,
while tumor-bearing
NYPD (4 of 17) and YD (11 of 59) animals developed
lung metastases at
similar frequencies, YB mice developed lung
metastases at a
significantly higher rate (12 of 18 animals) (Fig.
6B). To ensure that
metastases did not reflect differences in
tumor onset, metastasis was
assessed in a cohort of animals bearing
mammary tumors for 30 to 60 days (Table
1). During this observation
period, 50% of the YB
tumor-bearing mice develop metastatic lesions
in the lung, whereas only
10% of the YD animals exhibited detectable
metastatic lesions (Fig.
6B; Table
1). It should be noted that
due to the greater number of
mammary tumors detected on the YD
females, the tumor burden in the YD
animals was considerably greater
than that in the YB strains.
Therefore, the differences in metastatic
behavior between these tumor
cell types is even greater than these
pathological analyses would
suggest. Female YD mice carrying tumors
for extended periods (3 months
after initial palpation) eventually
developed metastatic mammary tumors
due to the extensive tumor
load, but the percentage of animals with
such lesions was significantly
lower than in YB mice. Interestingly,
mammary tumors induced by
the NYPD
neu mutant displayed
similar levels of metastatic infiltration.
Taken together, these
observations suggest that Neu receptors
coupled specifically to the
Grb2 adapter protein have enhanced
metastatic potential compared to Neu
receptor coupled to the Shc
adapter protein.
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FIG. 7.
Histopathology of mammary tumors induced by the various
neu autophosphorylation mutants. Photoimages show mammary
tumors from mice expressing the neu autophosphorylation
mutants NYPD (line 10) (A and B), YD (line 6) (C), and YB (line 2) (D).
All three animals exhibited well-differentiated glandular patterns. The
tumors were composed of cells with relatively small, oval to round
nuclei without significant pleomorphism. The cells were cytologically
identical to the cells seen in all Neu-induced tumors. YB consistently
had a better-differentiated glandular pattern (D). The size bar
indicates 0.1 mm.
|
|
Biochemical analyses of mammary tumors induced by the mutant Neu
receptors.
To ensure that Neu was activated to the same extent in
these tumors, Neu immunoprecipitates were subjected to immunoblot
analyses with antiphosphotyrosine antibodies. As expected,
tyrosine-phosphorylated Neu was detected in tumors derived from the YB
and YD mutants (Fig. 8A,lanes 3 to 5),
whereas Neu from NYPD-induced tumors was poorly tyrosine
phosphorylated, suggesting that the major in vivo tyrosine
autophosphorylation sites had been eliminated (lanes 1 and 2). The
differences in the levels of tyrosine-phosphorylated Neu were not
reflective of the amount of Neu expressed, since comparable levels of
Neu were detected in these samples (Fig. 8D). These Neu
immunoprecipitates were subjected to immunoblot analyses with Grb2 and
Shc-specific antibodies. While these tumor samples expressed comparable
Grb2 and Shc levels (Fig. 8E and F), Shc solely interacted with Neu
from YD-induced mammary tumors (Fig. 8B, lane 5), whereas Grb2 was
coupled to both YB and YD but not NYPD Neu receptors (Fig. 8C, lanes 3 to 5). Taken together, these observations indicate that mutant Neu
receptors that are expressed in these tumors are associated with their
expected substrates or partners.
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FIG. 8.
Neu is tyrosine phosphorylated in YB and YD-derived but
not NYPD-derived mammary tumors. Neu was immunoprecipitated (IP) from
the indicated breast tumor lysates. Two-thirds of each
immunoprecipitate was electrophoresed and subjected to phosphotyrosine
(pTyr) (A), Shc (B), and Grb2 (C) immunoblot (IB) analyses. Ab,
antibody. (D) Neu immunoblot of the remaining portion of each Neu
immunoprecipitate. Equivalent amounts (20 µg) of the same protein
lysates were subjected to immunoblot analyses with Shc (E)- or Grb2
(F)-specific antisera. Tumor lysates were derived from NYPD11, YB6, and
YD6 animals. The migration of YD in lane 5 of panel A is a gel
artifact, as Neu from the same immunoprecipitate comigrates with the
other mutant molecules (D).
|
|
Given that these Neu mutants remain coupled to their cognate adapters
in vivo, we further investigated their signaling capabilities.
Tumor
lysates were subjected to immunoblot analyses with antibodies
specific
to the activating phosphorylation sites of Erk1/2 and
Akt. While Erk1/2
activation was observed in YB- and YD-derived
mammary tumor lysates
(Fig.
9B, lanes 5 to 12), Erk was poorly
activated in the NYPD-induced mammary tumors (Fig.
9B, lanes 1
to 4)
despite expressing similar levels of Neu or Erk in these
tumor samples
(Fig.
8A, and
9B). These observations argue that
recruitment of either
Grb2 or Shc to Neu is required for efficient
activation of a Ras
signaling pathway.
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FIG. 9.
Activation of Erk and Akt phosphorylation in YB- and
YD-derived but not NYPD-derived mammary tumors. Equivalent amounts
(60 µg) of lysates from NYPD, YB, and YD tumors were subjected to Neu
and ErbB-3 immunoblot (IB) analyses (A). The same lysates were
similarly analyzed for phospho-Erk1/2 and Erk (B) and phospho-Akt and
Akt (C) levels as indicated. Each tumor lysate was derived from an
independent animal: NYPD10 (lanes 1 to 3), NYPD11 (lane 4), YB2 (lane
5), YB6 (lanes 6 and 7), YB7 (lane 8), YD5 (lanes 9 to 11), and YD6
(lane 12).
|
|
Activation of the phosphatidylinositol 3'-kinase (PI-3' kinase) through
Neu's transactivation of the ErbB-3 receptor ultimately
results in the
stimulation of Akt serine kinase (
51). Because
the tumor
samples possessed elevated levels of ErbB-3 capable
of interacting with
PI-3' kinase, we next examined whether a downstream
kinase, Akt, was
activated in this system. Despite similar ErbB-3
and Akt-1 levels,
Akt-1 was phosphorylated in YB and YD but not
NYPD tumors (Fig.
9C).
Together, these data suggest that mammary
tumors expressing YB and YD,
but not NYPD, activate two Ras effector
pathways, resulting in the
activation of both Erk and Akt
kinases.
| |
DISCUSSION |
The ability of activated growth factor RTKs to induce cellular
proliferation and differentiation is dependent on their capacity to
associate with and activate a number of substrates. We have demonstrated that Neu-mediated transformation is dependent on at least
four independent tyrosine autophosphorylation sites that can
functionally substitute for each other (9). Two of these functionally redundant sites (YB and YD) have been shown to
specifically couple to either the Grb2 or Shc adapter protein
9). Here we have demonstrated that YB and YD are
involved in activation of the Ras/Erk signaling pathway. Although both
of these phosphorylation sites are capable of recruiting the Grb2
adapter protein, only the YB phosphorylation site is dependent on a
functional Grb2 protein. To further explore the biological properties
of these Neu-coupled signaling pathways, we have generated
transgenic mice that express activated versions of Neu coupled
specifically to either the Grb2 (YB) or Shc (YD) adapter protein or a
Neu receptor lacking the major Neu tyrosine autophosphorylation sites
(NYPD) in the mammary epithelium. The results of these analyses
revealed that both the YB and YD strains were capable of efficiently
inducing mammary tumors, whereas the NYPD strains developed focal
mammary tumors only after a long latency period. However, only the
YB-induced mammary tumors were able to metastasize efficiently to
distal sites. Taken together, these observations argue that the YB and YD phosphorylation mutants are involved in activating both distinct and
common effector pathways.
The transforming potential of the different neu add-back
mutants correlated with their capacity to stimulate the Erk kinase cascade (Fig. 1C). Although all add-back neu mutants were
capable of efficiently activating the Erk kinase pathway, the
transforming activity of three of these mutants (YB, YD, and YE) was
inhibited by Rap1A, which acts as a competitive inhibitor of Ras
(20, 26, 38, 47). In contrast, the YC mutant appeared
refractory to Rap1A-mediated inhibition. One potential explanation for
this observation is that the YC phosphorylation site recruits a
signaling pathway that operates independently of the Ras signaling
pathway. Indeed, it has been demonstrated that the Crk adapter protein recruits the Rap1A-specific C3G exchange factor (16), and
this in turn results in stimulation of MAP kinase pathway (22,
23). Given the observation that Crk specifically interacts with
site C in vitro (Fig. 3), it is likely that site C is actually involved in the activation of Rap1A and stimulation of the Erk kinases, thus
explaining its resistance to Rap1A inhibition. Further evidence supporting the contention that site C funnels through a signaling pathway distinct from the other transforming add-back mutants stems
from recent observations that reovirus infection selectively kills
Ras-transformed cells through lytic virus production (8). We and our collaborators have recently demonstrated that reovirus infection of YB-, YD-, and YE-expressing cells results in
virus-mediated cell lysis but is incapable of killing cells
transformed by the YC mutant (P. Lee, D. Dankort, and W. J. Muller, unpublished observations). Taken together, these data again
argue that both Ras-dependent and Ras-independent pathways are
involved in Neu-mediated transformation.
We have conducted further detailed mutagenesis analysis of the Grb2 and
Shc binding sites to determine that the YB and YD phosphorylation sites
are highly specific binding sites for these adapter proteins. The
results of these analyses demonstrate that the transforming potential
of these mutants is directly correlated with ability of these sites to
recruit Grb2 and Shc, respectively (not shown). Although YB and YD
mutants are capable of either directly or indirectly recruiting the
Grb2 protein, only the YB Neu mutant is dependent on Grb2 function to
stimulate DNA synthesis (Fig. 6). These observations argue that Shc has
the ability to induce DNA synthesis in a Grb2-independent manner.
Consistent with this view, it has recently been demonstrated that
tyrosines 239 and 240 within Shc are capable of stimulating mitogenesis and cell survival independent of the Grb2/Ras signaling pathway (16, 17). Although the Shc-associated proteins have yet to be identified, several unidentified proteins specifically associate with Shc through these tyrosine phosphorylation sites
(49). Identification of these novel proteins associated
with Shc will provide important insight into the role of Shc in
Neu-mediated proliferation.
Further evidence supporting the contention that Shc and Grb2 utilize
distinct effector pathways stems from studies of transgenic mice
expressing the YB and YD Neu mutants in the mammary epithelium. Mammary
epithelial expression of either YB or YD efficiently induced mammary
tumors in these strains after a latency period ranging from 102 to 152 days (Fig. 6). In contrast, a maximum of 50% (depending on the NYPD
line) of NYPD female transgenic mice developed focal mammary tumors
after a 351-day observation period. These observations argue that
coupling of Neu to either the Grb2 (YB strains) or Shc (YD strains)
adapter protein is able to efficiently promote transformation of
mammary epithelial cells. In fact, the 100% of the mammary tumor
phenotype is higher than the 80% penetrance phenotype observed with
the comparable activated neu strains (43). The
difference in biological behavior of these strains may reflect the fact
that the latter activated neu strains still carry the negative regulatory tyrosine residue (tyrosine 1028) whereas the YB and
YD strains do not (9).
The potent transforming activity of YD and YB strains was associated
with their capacity to couple to both the Erk and Akt kinase cascades.
In addition, mammary tumor progression in the YB- and YD-induced
mammary tumors was also associated with a dramatic upregulation of the
ErbB-3 RTK and activation of the associated PI-3' kinase signaling
pathway. Thus, stimulation of both Ras and PI-3' kinase-dependent
pathways was sufficient to promote efficient mammary tumor induction.
In contrast to these observations, the NYPD-induced mammary tumors
failed to exhibit significant activation of either Erk or Akt kinase,
suggesting that mammary tumorigenesis in this model system occurs
through signaling pathways independent of either Ras or PI-3' kinase.
Indeed, we have recently demonstrated that the NYPD mutant still
retains the capacity to couple to the Src family kinases and itself
retains wild-type kinase activity in vitro (Dankort and Muller,
unpublished). Conceivably, stimulation of the Src family kinases may be
responsible for the residual transforming activity exhibited by the
NYPD neu mutant. Indeed, it has been demonstrated that
mammary epithelial expression of activated Src is capable of inducing
focal mammary tumors after a long latency period (53).
Another possible mechanism by which the NYPD neu mutant is
capable of inducing mammary tumors is through reversion of specific Neu
autophosphorylation sites. Indeed, previous studies have shown that
10% of the mammary tumors arising in transgenic mice expressing a
mutant polyomavirus middle T oncogene decoupled from the Shc adapter
molecule possess reversion mutations that restore the ability of Shc to
efficiently couple to polyomavirus middle T antigen (54).
Finally, it is also possible that the NYPD mutant induces tumorigenesis
through the formation of specific heterodimers with other members of
the epidermal growth factor receptor family. In this regard, we have
noted that tumors derived from NYPD strains express elevated levels of
ErbB-3 (Fig. 9). Future studies with these NYPD strains should provide
important insight into the contribution of each of these coupled
signaling pathways in Neu-mediated tumorigenesis and metastasis.
Although mammary epithelial expression of either the YB or YD mutant
efficiently induced mammary tumors, histological examination of these
Neu-induced mammary tumors have revealed that they have distinct
morphologies (Fig. 5 and 7). In particular, the YB tumors displayed
papillary morphology, whereas the YD-induced tumors developed a nodular
phenotype similar to that displayed by the parental activated
neu strains. The differences in the morphologies may reflect
differences in the repertoire of signaling proteins coupled to Shc and
Grb2. Indeed, it has been demonstrated that in addition to Grb2, Shc
couples to several unidentified proteins (49). Moreover,
in certain cell types Shc can signal independent of Grb2/Ras activation
through a pathway involving the upregulation of the c-Myc transcription
(16). Taken together, these observations argue that YB and
YD neu mutants function through both common and distinct
signaling pathways.
Another potentially important phenotypic difference between the
YB and YD strains is that only the YB strains efficiently develop
metastatic lesions. The difference in the metastatic properties of these neu mutants is not due to difference in rate of
tumor development since the nonmetastatic YD tumors actually develop a
much greater tumor load. One potential explanation for the differential metastatic properties of the YB-induced tumors is that Neu is coupled
to signaling pathways that confer enhanced metastatic properties to
these cells. Although the molecular basis for this difference in
metastatic phenotype is unclear, we have previously shown that the
dosage of Grb2 can have a profound effect on tumor induction in
transgenic mice (7). In addition to affecting tumor
induction, reduction of Grb2 levels also impairs ductal outgrowth of
the mammary epithelium (7), suggesting that it may
be involved in promoting epithelial cell migration. Direct recruitment of Grb2 to the Met receptor appears to confer
metastatic potential to engineered cell lines (15), and
there appears to be a direct link with Grb2 to sustain myoblast
proliferation and/or survival during migration from the somites
in Met receptor knock-in mice (28). Given the
importance of migration in metastatic disease, it is conceivable
that the YB mutant, through its direct interaction with Grb2, promotes
metastasis through stimulation of cell migration and or survival of
migrating cells. In this regard, it has been demonstrated that
phosphospecific antibodies to Neu tyrosine phosphorylation site 1253 (YE) appear to detect a minority of ErbB-2 human breast cancers that
exhibit the invasive phenotype (11). It is conceivable that other ErbB-2 phosphorylation sites such as YB (tyrosine 1144) may
also predict particularly aggressive human breast cancer phenotypes. Future studies with these mutant Neu strains and conditional ablation of Grb2 in mice should provide important insights into the molecular basis of metastatic progression.
| |
ACKNOWLEDGMENTS |
We thank Luika Timmerman for comments. We are also grateful to
Monica Graham, Linda Wei, and Judy Walls for technical support.
This work was supported by a CBCRI grant awarded to W.J.M. This work
was also partially supported by grants awarded to R.G.O. (National
Cancer Institute grant CA74507 and Cancer Center Support grant P30
CA30199). D.D. was supported by scholarships from Cancer Research
Society and NSERC. W.J.M. is supported by an MRC Scientist award.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Institute
for Molecular Biology and Biotechnology, McMaster University, 1280 Main St. West, LSB 327, Hamilton, Ontario, Canada L8S 4K2. Phone: (905) 525-9140, ext. 27306. Fax: (905) 521-2955. E-mail:
mullerw{at}mcmail.cis.mcmaster.ca.
Present address: Cancer Research Institute, University of
California, San Francisco, San Francisco, CA 94143-0128.
| |
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Molecular and Cellular Biology, March 2001, p. 1540-1551, Vol. 21, No. 5
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.5.1540-1551.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
