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J. Biol. Chem., Vol. 276, Issue 29, 26814-26818, July 20, 2001
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,
From the § Ovarian Cancer Program, Fox Chase Cancer
Center, Philadelphia, Pennsylvania 19111 and the
Department of Biochemistry and Winship Cancer Institute,
Emory University School of Medicine, Atlanta, Georgia 30322
Received for publication, February 28, 2001, and in revised form, April 17, 2001
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
REFERENCES
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Disabled-2 (Dab2) is a putative tumor suppressor
in breast and ovarian cancers. Its expression is lost in a
majority of tumors, and homozygous deletions have been identified in a
small percentage of tumors. Dab2 expression is absent or very
low in the majority of breast and ovarian cancer cell lines, including
MCF-7 and SK-Br-3 breast cancer cells. Transfection and expression of
Dab2 in MCF-7 and SK-Br-3 cells suppress tumorigenicity. The cells
reach a much lower saturation density and have reduced ability to form
colonies on agar plates. In examining the signal transduction pathway
of Dab2-transfected cells, we found that serum-stimulated c-Fos
expression was greatly suppressed; however, the effects of Dab2 on MAPK
family kinases were not as consistent. In MCF-7 and SK-Br-3 cells,
although c-Fos expression was suppressed, the Erk1/2, JNK, and
p38MAPK activities were unchanged or even increased.
Serum-stimulated c-Fos expression is dependent on MAPK/Erk
activity because the MEK inhibitor PD98059 suppresses Erk activity and
c-Fos expression. Therefore, Dab2 appears to uncouple MAPK activation
and c-fos transcription. Thus, we conclude that Dab2
re-expression suppresses tumorigenicity by reducing c-Fos expression at
a site downstream of the activation of MAPK family kinases.
Because Dab2 is frequently lost in cancer, the uncoupling of
MAPK activation and c-Fos expression may be a favored target for
inactivation in tumorigenicity.
Mitogen-activated kinases
(MAPK),1 also known as
extracellular signal-regulated kinases (Erk), are the key downstream
targets of the Ras pathway (1-3). The MAPK pathway is used in numerous signaling systems involved in cell growth, differentiation, and development (1-5). The Ras/MAPK pathway has the potential for oncogenic transformation of cells (6, 7), as revealed by the
discoveries of viral oncogenes such as v-Ras, v-Raf, v-Jun, and v-Fos.
The cellular components of these oncogenes function in the Ras/MAPK
pathway. The pathway is also a key target for cell transformation in
tumor development in that about 50% of cancers harbor an activating
mutation of Ras (6, 8). The cell regulatory system has developed an
intricate network for the fine regulation of the Ras/MAPK pathway to
counter cell transformation. For example, normal human fibroblasts will
undergo senescence or programmed cell death when an activated Ras is
introduced (9, 10). Growth factor-stimulated Ras signals are also
feedback regulated/inhibited following growth factor binding by
receptor degradation (11), dissociation of Sos and Grb2 upon
phosphorylation of Sos by activated MAPK (12-15), by the enzymatic
actions of Ras GAP, and by the actions of phosphatases specific for the
kinases in the pathway. Additionally, the surrounding environment of
the cells, such as contact with the extracellular matrix, can modify the effects of growth factors on the activation of Ras/MAPK pathway (16, 17). In breast and ovarian cancers, mutations of Ras are rare, and
activating mutations of other components in the Ras/MAPK pathway are
also uncommon (18). It is believed that regulators in the fine-tuning
of the Ras/MAPK pathway are lost, resulting in aberrant activation of
the pathway.
The conservation of the Ras/MAPK pathway in yeast, Caenorhabditis
elegans and Drosophila has helped to delineate the
components and regulation of the pathway. In mammalian cells, the
growth factor binds to its tyrosine kinase receptor and stimulates its autophosphorylation on its tyrosine residues. The phosphotyrosine residues on the receptor act as a docking site for assembling critical
intracellular signaling molecules at the cell membrane to initiate a
signal cascade (19, 20). The adapter molecule Grb2 binds to the
tyrosine receptor through Shc or directly to the phosphotyrosine
residue, bringing associated Sos to activate Ras on the plasma
membranes. Ras is activated upon conversion to the GTP bound form and
initiates the Raf-1/MEK/MAPK kinase cascade. An established target for
MAPK is Elk-1, a transcription factor required for transactivation of
c-Fos (21-23). c-Fos was first identified as a cellular counterpart of
the viral oncogene capable of cell transformation (24), and its
expression is the target of regulation in cell growth control (25).
c-fos is an immediate early gene whose transcription is
activated by serum and growth factors, and its expression is a key
switch in cellular regulation (24, 25). c-Fos, together with c-Jun,
form the AP-1 transcriptional complex required for the transcription of many genes important for cell growth, differentiation, and
transformation (26, 27).
We now report that the expression of c-Fos is a target for the
regulatory function of Disabled-2 (Dab2), a candidate tumor suppressor
of breast and ovarian tumors (28-30). Dab2, a mammalian ortholog of
the Drosophila Abl kinase-interacting protein Disabled (31),
was isolated as a mitogen responsive phosphoprotein (32). Dab2 was
identified by differential displaying to be a gene whose expression was
absent in ovarian cancer cells but present in normal ovarian epithelial
cells (28). We have previously found that Dab2 is expressed in breast
and ovarian epithelial cells, but its expression is lost in the
majority (about 85%) of breast and ovarian tumor cells (28, 29, 30).
Dab2 contains a phosphotyrosine-interacting domain (PID, or PTB) in its
N terminus and a proline-rich, SH3-binding domain in its C terminus,
resembling an adapter molecule (32). Its binding to Grb2, competing
with Sos, leads to the hypothesis that Dab2 is a Ras/MAPK pathway
regulator that is lost in cancer (33). We found that re-expression of
Dab2 in breast cancer cells leads to suppression of c-Fos expression
and cell growth inhibition. Surprisingly, Dab2 does not inhibit MAPK
activity. Thus, a regulatory step in the Ras/MAPK pathway is the
uncoupling of the activation of MAPK and transcriptional activation of
c-Fos, mediated by Dab2. Tumor cells likely abrogate the essential
regulation of the Ras/MAPK pathway in normal cells by the elimination
of Dab2, which might contribute to cell transformation.
Materials--
Kinase inhibitors, PD98059 and SB202190, were
purchased from Calbiochem (San Diego, CA). Tissue culture plastic wares
were obtained from Fisher Scientific Inc. (Springfield, NJ). DMEM
medium was purchased from Mediatech (Herndon, VA); fetal bovine serum (FBS) was obtained from Atlanta Biologicals (Atlanta, GA);
antibiotic-antimycotic (100×) solution, LipofectAMINE, and serum-free
Opti-MEM I medium were purchased from Life Technologies, Inc. (Grand
Island, NY). The ECL Western blot detection kit was purchased from
PIERCE (Rockfort, IL); Hybrisol I hybridization solution was from
Intergen Inc. (Purchase, NY); positively charged nylon membranes were
from Roche Molecular Biochemicals; general chemicals and solvents
including Me2SO, ethanol, isopropyl alcohol, and agarose
were from Sigma or Fisher and were of reagent grade or higher.
Cell Culture--
MCF-7 and SK-Br-3 human breast cancer cells
were purchased from ATCC. The cells were cultured in DMEM with 10% FBS
supplemented with 1% non-essential amino acid mix and
antibiotic-antimycotic solution.
Antibodies and Western Blot--
Anti-Dab2 antibodies were
characterized previously (30-32). Anti-p96 antibodies were purchased
from Transduction Labs. (Lexington, KY); anti-c-Fos was from UpState
Biotechnology (Lake Placid, NY); anti- Cell Transfection--
The full-length human DAB2 cDNA
(GenBankTM accession number AF188298) was inserted into the
pcDNA/zeo eukaryotic expression vector (Invitrogen, La Jolla, CA).
Plasmid DNA was purified using the Qiagen Maxiprep column, and
LipofectAMINE reagent was used for transfection. Briefly, 2 µg of
Dab2 expression construct or vector control plasmid DNA was mixed with
20 µl of LipofectAMINE in 1 ml of Opti-MEM and was added to cells for
16 h. The transfection mix was removed, and fresh DMEM containing
10% FBS was added. After 12 h, selection medium (DMEM with 10%
FBS and 300 ng/ml of Zeomycin) was added to the cells. Following a
10-12 day selection with change of medium every 2 days to removed dead
cells, selected clones were isolated and collected by cloning rings,
expanded by further culturing, and examined for Dab2 expression by
Western blotting.
Cell Growth Analysis--
Cell growth was determined by counting
under a microscope and the MTT assay (Promega). For cell counting,
cells (around 105 per plate) were plated in 35-mm tissue
culture dish (6-well dish), and medium was changed daily. At the
indicated times, cells were harvested in 1 ml of trypsin-EDTA,
collected by centrifugation and resuspended in 100 µl of
phosphate-buffered saline for counting. For the MTT assay, cells
(around 104) were plated in 96-well plates, and medium was
changed daily. On the indicated day, the MTT dye was added and
incubated with the cells for 2 h in the tissue culture incubator.
The reaction was stopped by addition of cell solubilization solution.
After 2 h at room temperature, the absorbance of the solution at
570 nm was measured with a microplate reader.
Colony Formation on Agar Plates--
Cells were embedded in a
0.3% low melting point agarose top layer in culture medium, plated on
top of a 0.6% agarose bed in DMEM containing 10% FBS and complete
supplements. The agarose plates were incubated at 37 °C for 3 weeks,
with addition of fresh medium every 3 days.
Cell Cycle Analysis by Flow Cytometry--
Cells on 100-mm
plates were harvested with trypsin-EDTA solution and pelleted by
centrifugation. The cells were then fixed with 70% ethanol, pelleted,
and resuspended in propidium iodine staining solution for 30 min at
4 °C. The stained cells were analyzed by flow cytometry.
Establishment of Dab2 Expression in MCF-7 and SK-Br-3 Breast Cancer
Cells--
We have previously found that Dab2 is expressed in breast
and ovarian epithelial cells, but its expression is lost in the majority (about 85%) of breast and ovarian tumor cells tested (28, 29,
30). Forced expression of Dab2 in tumor cells reduces cell growth,
induces cell death, and suppresses tumorigenicity in the nude
mouse xenograft model (29, 34). To further determine the biological
consequence of Dab2 loss for the tumor cells and to examine the signal
transduction pathway affected, we have transfected and established Dab2
expression in MCF-7 and Sk-Br-3 breast tumor cells. Dab2 expression is
absent in these two breast carcinoma cell lines (30).
Following transfection of the human Dab2 cDNA in the pcDNA
expression vector into MCF-7 breast cancer cells, 26 zeomycin-resistant clones were selected. Of these clones, only two clones were found to
express Dab2 as detected by Western blot, and a single clone (clone 8)
still retained Dab2 expression upon expansion of the cells in culture
(Fig. 1A). In contrast, 22 of
64 Sk-Br-3 clones selected retained some expression of the transfected
Dab2, and the three high expressing clones 49, 50, and 57 were chosen
for further analysis (Fig. 1B). Three randomly selected
vector transfected clones of each cell line were expanded for use as
controls.
Transfection and Expression of Dab2 Inhibit Cell Growth and
Transformation in MCF-7 and Sk-Br-3 Breast Cancer Cells--
Upon
establishment of the Dab2-expressing cells, we first characterized the
growth properties of the cells. Transfected MCF-7 cells (clone 8) were
found to grow more slowly in either low (0.1%) or high (10%) serum
compared with vector-transfected controls (Fig.
2A). A similar growth
retardation was found in the three Dab2-expressing SK-Br-3 clones
compared to three vector-transfected clones (Fig. 2B). The
Dab2-transfected MCF-7 cells were found to have a reduced ability to
form colonies on agar plates; MCF-7-Dab2 clone 8 cells formed fewer
(about 20% of control) and smaller colonies than vector-transfected
clones (data not shown). All three clones of Dab2-transfected Sk-Br-3
cells also had a reduced ability to form colonies on agar plates (not
shown). All four selected Dab2-expressing tumor cell clones were
analyzed for cell cycle parameters using flow cytometry (Table
I). Compared with vector-transfected and
non-transfected cells, both MCF-7 and Sk-Br-3 cells expressing Dab2
have about a 50% lower percentage of cells in S phase and about 25%
lower percentage of cells in G2/M phase, suggesting a
prolonged G1 phase. These results are consistent with
previous reports with different tumor cell lines on the negative cell
growth regulatory properties and tumor suppressive activity of Dab2
(29, 35). Our goal is to analyze the effects on the cellular signal
transduction pathways by the Dab2 protein in these cells.
Dab2 Transfection and Expression Inhibits Serum-stimulated c-Fos
Expression--
Next, we examined the possible changes in mitogenic
signaling in Dab2-expressing cells compared with vector-transfected
cells. We observed by both Western and Northern blots a reduction of c-Fos expression upon serum stimulation of the Dab2-expressing cells.
For both MCF-7 cells and Sk-Br-3, c-Fos is induced by serum at 30 min
and is maximal at 60 min in vector-transfected cells (and also in
non-transfected cells). In Dab2-expressing MCF-7 cells (clone 8) (Fig.
3) and a representative clone 49 of
Dab2-expressing SK-Br-3 cells (Fig. 5B), little c-Fos
expression is induced by serum. The same effect of Dab2 expression on
c-Fos expression was also observed in transfection of tumor cells with
Dab2 using an adenoviral vector in our previous investigation (34).
Thus, the suppression of c-Fos expression is not because of the
particular properties of the selected cell clones but the result of
Dab2 expression.
Effect of Dab2 Expression on the Activation of Erk1/2, JNK, and
p38MAPK Kinases following Serum Stimulation--
It has
been established that MAPK activation leads to c-Fos transcription and
increases in AP-1 activity (21-23). To our surprise, however, no
reduction in MAPK activity was observed in Dab2-expressing MCF-7 or
SK-Br-3 cells although c-Fos expression was suppressed. To eliminate
possible artifacts and to confirm this observation, we performed
Western blot analysis to determine c-Fos expression and MAPK activation
simultaneously on the same blot by including a proper mix of anti-c-Fos
and anti-phospho-MAPK (activated) antibodies in the same incubation.
c-Fos expression and MAPK activation by serum were determined for clone
8 Dab2-expressing MCF-7 cells (Fig. 3), and a representative clone 49 of Dab2-expressing Sk-Br-3 cells (Fig. 5B). In the Dab2
expressing MCF-7 cells, though serum-stimulated c-Fos expression is
greatly reduced compared with vector-transfected control, MAPK activity
is enhanced as detected by phosphopeptide antibodies in this experiment
(Fig. 3). Similar effects of Dab2 expression in SK-Br-3 on c-Fos
expression and MAPK activation were found in Dab2-expressing clones
(not shown). We also investigated and found no effect of Dab2
expression on Ras and Raf-1 activation (not shown). Thus, restoration
of Dab2 expression appears to dissociate MAPK activation and c-Fos
expression in tumor cells.
The effect of Dab2 expression on other MAPK family kinases including
JNK and p38MAPK kinases was also investigated. Dab2
expression appears to have no significant and consistent effect on
serum-stimulated JNK activity as detected by Western blot with
JNK-phosphopeptide specific antibodies (Fig. 3). In either
Dab2-expressing or vector-transfected MCF-7 and SK-Br-3 cells, serum
stimulation did not notably activate p38MAPK as detected by
anti-p38MAPK phosphopeptide antibodies (not shown), though
in the same experiment, strong activation was observed in a positive
control using anisomycin as a stimulating agent.
Effect of Kinase Inhibitors on c-Fos Expression--
The effect of
MAPK family kinase activation on c-Fos expression was further explored
in MCF-7 and Sk-Br-3 cells using kinase inhibitors PD98059 and
SB202190. In MCF-7 cells, the MEK inhibitor PD98059 inhibited MAPK
activation and c-Fos expression in a dose-dependent manner
(Fig. 4A), indicating
PD98059-inhibitable MAPK activity is necessary for serum to activate
c-Fos expression. In contrast, the p38MAPK inhibitor
SB202190, although it appears to reduce the basal state of MAPK
activity, had no inhibitory effect on serum-stimulated MAPK (Erk)
activation and c-Fos expression (Fig. 4B). In comparison, inhibition of c-Fos expression by MEK inhibitor PD98059 (Fig. 5A) mechanistically differed
from inhibition of c-Fos expression by Dab2 expression (Fig.
5B) in SK-Br-3 cells. Thus, Erk1/2, but not
p38MAPK, is required for serum-stimulated c-Fos expression.
Unlike PD98059, Dab2 restrains c-Fos expression at a step between MAPK
activation and c-Fos expression without inhibiting MAPK activity (Fig.
6).
Effect of Dab2 Expression on the Phosphorylation/Activation of
Elk-1--
It has been established that MAPK phosphorylates/activates
the transcription factor Elk-1, and activated Elk-1 binds to the c-Fos
promoter and activates expression of c-Fos (21-23). We found that Dab2
expression reduced the serum-stimulated phosphorylation of Elk-1 in
MCF-7 cells and in Sk-Br-3 cells (not shown). To explore the mechanism
for the effects of Dab2 on MAPK and Elk-1, we examined the physical
interaction between Erk1/2, Elk-1, and Dab2. In co-immunoprecipitation experiments, we found that Dab2 is not associated in any significant way with Erk1/2 or Elk-1, either the phosphorylated or unphosphorylated proteins. Thus, through an indirect but unclear mechanism, Dab2 uncouples MAPK activation and Elk-1 phosphorylation.
Conclusion--
Dab2 is frequently lost in breast and ovarian
tumors (30). We have shown here in MCF-7 and SK-Br-3 breast cancer
cells, and others have shown in additional tumor cells (29, 35), that
transfection and expression of Dab2 suppresses tumorigenicity: the
cells reach a much lower saturation density, have reduced ability to
form colonies on agar plates, and have suppressed ability to develop
tumors in nude mice. In analysis of signal transduction pathways
affected, we have found that serum-stimulated c-Fos expression is
greatly suppressed. Expression of c-Fos is activated through the action
of MAP kinase phosphorylation (21-23). Surprisingly, the Erk1/2, JNK
kinase, and p38MAPK activities were unchanged or even
increased upon serum stimulation in transfected Dab2-expressing cells
compared with vector-transfected cells. Thus, we conclude that Dab2
re-expression suppresses tumorigenicity by uncoupling MAPK activation
and c-Fos expression. Although Dab2 could have additional effects on
the cells, the suppression of c-Fos expression may be sufficient to
suppress cell growth and transformation.
It is well established that the Ras pathway through a cascade of
kinases, results in activating the expression of immediate early genes
such as c-Fos (21-23). Normally, Ras/MAPK activity is well correlated
with c-Fos expression. MAP kinases, Erk1 and Erk2, upon activation will
phosphorylate Elk-1, an ETS family transcription factor (21).
Phosphorylation of Elk-1 at serine 383 activates its ability to
participate in the transcription complex that transcribes c-Fos
(21-23). Two recent studies report that MAPK activation and Elk-1
phosphorylation/activation are uncoupled (36, 39). KSR, a mammalian
ortholog of the Drosophila kinase suppressor of Ras (KSR),
can inhibit Elk-1 phosphorylation without affecting MAPK activation
(36). The affect of KSR on inhibition of Elk-1 phosphorylation is
believed to act through the activation of the Ca2+ and
calmodulin-regulated PP2B (calcineurin), the major phosphatase for
Elk-1 (37, 38). The mechanism for the activation of PP2B by KSR is
still unknown. Another report shows that adapter protein Gab2, the
probable ortholog of the Drosophila daughter of sevenless (DOS), acts to uncouple signaling from MAPK to Elk-1, though no mechanism is yet known (39). It is interesting that both Dab2 and Gab2
are Grb2-binding proteins (32, 39), which may provide some common
mechanism in uncoupling MAPK and Elk-1. In normal cells that are
Dab2-positive, the ability to uncouple MAPK activation and c-Fos
expression will enable the cells to achieve precise control of
biological processes, because the Ras/MAPK pathway is widely used for
cell growth, differentiation, and development (1-5).
There are several possible mechanisms for Dab2 to uncouple MAPK and
Elk-1. First, Dab2 may act to dephosphorylate Elk-1, similar to KSR in
activating PP2B. Dab2 may do so by inducing calcium influx or
recruiting PP2B to a particular cellular location. Alternatively, Dab2
may inhibit phosphorylation of Elk-1 by MAPK. We have found no physical
association between Dab2 and Erk1/2 or Elk-1. Dab2 could still prevent
the phosphorylation of Elk-1 by blocking nuclear entry of the activated
MAPK or sequestration of Elk-1 from being phosphorylated by the
activated MAPK. We are currently investigating these possibilities.
In summary, we have uncovered a regulatory site in the Ras pathway by
the candidate tumor suppressor Dab2: the uncoupling of MAPK activation
and c-Fos expression (Fig. 6). Suppression of c-Fos expression is
consistent with the finding that Dab2 expression retards the
progression of the cells through G1 phase (Table I). Dab2
is lost in the majority of breast and ovarian cancer cells and tissues.
Thus, in non-tumorigenic normal cells, the Ras pathway is regulated by
Dab2-mediated uncoupling of MAPK activation and c-Fos expression. This
appears to be a favored target for inactivation during tumorigenicity;
tumor cells eliminate Dab2 and thus a regulatory site in the Ras
pathway. The loss of Dab2-mediated regulation of c-Fos expression
likely contributes to malignancy.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
REFERENCES
-actin was from Sigma;
anti-Erk1/2 and phospho-Erk1/2 were from Biolab and Cell Signaling
Technology Inc. (Beverly, MA); anti-Elk-1 and anti-phospho-Elk-1 were
from Promega and Santa Cruz Biotechnology (Santa Cruz, CA). Western
blotting was performed according to standard procedures, as described
previously (33). In some cases, after gaining experience with usage of
a single antibody, two or more antibodies were used in the same
incubation to detect various molecular weight proteins simultaneously.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
REFERENCES
View larger version (46K):
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Fig. 1.
Establishment of Dab2-transfected MCF-7 and
Sk-Br-3 breast cancer cells. MCF-7 (A) and Sk-Br-3
(B) breast cancer cells on 35-mm wells were transfected with
human Dab2 cDNA expression construct or pcDNA3 vector alone
using LipofectAMINE. Two days following transfection, the cells were
transferred to 100-mm plates and cultured in medium with 300 ng/ml
Zeomycin. The medium was changed every 2 days to remove floating dead
cells, and Zeomycin-resistant colonies formed were harvested using
cloning cylinders and plated on 24-well plates. The cell cultures were
expanded, and a fraction was used for analysis for Dab2 expression by
Western blot. -actin was determined on the same blot as a
protein-loading control.
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Fig. 2.
Characterization of MCF-7 and Sk-Br-3 cell
clones transfected with Dab2. Growth curve for MCF-7
vector-transfected or Dab2-transfected clone 8 (A) and
SK-Br-3 vector-transfected or Dab2-transfected clone 49 (B)
cells. Cells on 35-mm plates were cultured in medium with 1 or 10%
serum. Cell numbers were determined by counting (A) or MTT
assay (B). Error bars indicate S.D. from
measurement of triplicate plates. Data shown are representative of five
or more independent experiments using either cell counting or the MTT
assay.
Cell cycle parameters of the transfected cell clones
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Fig. 3.
Effect of Dab2 expression on activation of
Erk1/2, JNK, and p38MAPK kinases following serum
stimulation. MCF-7 cells transfected with vector or Dab2 (clone 8)
were seeded on 35-mm plates. The cells were cultured without serum for
18 h and then stimulated with serum for 0, 15, 30, 60, and 120 min. Cells were immediately washed twice with cold phosphate-buffered
saline, lysed with SDS gel loading buffer and boiled for 5 min. The
cell lysates were analyzed by Western blotting for MAPK activation with
anti-phosphopeptide antibodies for Erk1/2, JNK, and
p38MAPK. Expression of c-Fos was determined simultaneously
on the same blot as MAPK activation. -Actin was used as a loading
control.
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Fig. 4.
Inhibition of serum-stimulated c-Fos
expression by PD98059 and SB202190 in MCF-7 cells. MCF-7 cells
were seeded onto 35-mm plates and grown to 80% confluency and were
then cultured without serum for 18 h. By the end of the 18-h
incubation, serial concentrations of PD98059 (A) or SB202190
(B) were added and incubated for 30 min. The cells were then
stimulated with 10% serum in the presence of the same concentration of
the compounds. Cell lysates were prepared at 0, 15 (or 30), and 60 min
time points for Western blot analysis using antibodies for c-Fos and
phospho-Erk1/2 to determine c-Fos expression and MAPK activation
simultaneously.
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Fig. 5.
Comparison of Dab2 expression and PD98059 on
the inhibition of serum-stimulated c-Fos expression in SK-Br-3
cells. A, SK-Br-3 cells (untransfected) were seeded
onto 35-mm plates and were cultured without serum for 18 h. By the
end of the 18-h incubation, PD98059 (100 µM) was added to
one set of cells for 30 min. The cells were then stimulated with 10%
serum, with or without addition of PD98059 (100 µM) for
0, 15, 30, and 60 min. The cell lysates were analyzed for c-Fos
expression and MAPK activation by Western blotting. B,
SK-Br-3 cells transfected with vector or Dab2 (clone 49) were seeded
onto 35-mm plates, and were cultured without serum for 18 h. The
cells were then stimulated with 10% serum. Cell lysates were harvested
at 0, 15, 30, and 60 min and were assayed for c-Fos expression and MAPK
activation simultaneously by Western blot analysis.
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Fig. 6.
Schematic model presentation of Dab2
regulation of c-Fos expression. Serum and growth factor activates
Ras and MAP kinase, which is inhibited upon addition of the MEK
inhibitor PD98059. Phosphorylation of Elk-1 by MAPK is required for
serum-stimulated c-Fos transcription. The pathway is regulated by Dab2
by uncoupling MAPK activation and c-Fos expression. This regulatory
mechanism is often absent in tumor cells because of the loss of
Dab2.
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ACKNOWLEDGEMENTS |
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We thank Malgorzata Rula and Jennifer Smedberg for technical assistance.
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FOOTNOTES |
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* These studies were supported by Grants R01 CA79716 and R01 CA75389 (to X. X. Xu) from NCI, National Insitutes of Health, and funds from OCRF (New York, NY).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
¶ To whom correspondence should be addressed: Ovarian Cancer Program, Fox Chase Cancer Center, Philadelphia, PA 19111. Tel.: 215-728-2188; Fax: 215-728-2741; E-mail: X_Xu@fccc.edu.
Published, JBC Papers in Press, May 18, 2001, DOI 10.1074/jbc.M101820200
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ABBREVIATIONS |
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The abbreviations used are: MAPK, mitogen-activated protein kinase; Erk, extracellular-signal regulated kinase; GST, glutathione S-transferase; Dab2, Disabled-2; JNK, Jun N-terminal kinase; MEK, MAPK or Erk kinase; Sos, Son-of-sevenless; DOS, daughter of sevenless; KSR, kinase suppressor of Ras; GAP, GTP-activating protein; Grb2, growth factor receptor binding 2; PID, phosphotyrosine-interacting domain; PTB, phosphotyrosine binding domain; FBS, fetal bovine serum; Abl kinase, Abelson kinase; DMEM, Dulbecco's modified Eagle's medium; MTT, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide.
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REFERENCES |
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
REFERENCES
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