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Molecular and Cellular Biology, September 1998, p. 5148-5156, Vol. 18, No. 9
0270-7306/98/$00.00+0
Persistent Activation of Mitogen-Activated Protein
Kinases p42 and p44 and ets-2 Phosphorylation in Response to
Colony-Stimulating Factor 1/c-fms Signaling
Lindsay F.
Fowles,1
Michele L.
Martin,2
Lori
Nelsen,2
Katryn J.
Stacey,1
Douglas
Redd,2
Ying Mei
Clark,2
Yoshikune
Nagamine,3
Martin
McMahon,4
David A.
Hume,1 and
Michael C.
Ostrowski2,*
Departments of Microbiology and Biochemistry
and the Centre for Molecular and Cellular Biology, University of
Queensland, Queensland Q4072, Australia1;
Department of Molecular Genetics, Ohio State University,
Columbus, Ohio 432102;
Friedrich-Miescher-Institute, Basel,
Switzerland3; and
DNAX Research
Institute, Palo Alto, California 943044
Received 22 December 1997/Returned for modification 6 March
1998/Accepted 25 June 1998
 |
ABSTRACT |
An antibody that specifically recognized phosphothreonine 72 in
ets-2 was used to determine the phosphorylation status of endogenous
ets-2 in response to colony-stimulating factor 1 (CSF-1)/c-fms signaling. Phosphorylation of ets-2 was detected in primary
macrophages, cells that normally express c-fms, and in fibroblasts
engineered to express human c-fms. In the former cells,
ets-2 was a CSF-1 immediate-early response gene, and
phosphorylated ets-2 was detected after 2 to 4 h, coincident with
expression of ets-2 protein. In fibroblasts, ets-2 was constitutively
expressed and rapidly became phosphorylated in response to CSF-1. In
both cell systems, ets-2 phosphorylation was persistent, with maximal
phosphorylation detected 8 to 24 h after CSF-1 stimulation, and
was correlated with activation of the CSF-1 target urokinase
plasminogen activator (uPA) gene. Kinase assays that used recombinant
ets-2 protein as a substrate demonstrated that mitogen-activated
protein (MAP) kinases p42 and p44 were constitutively activated in both
cell types in response to CSF-1. Immune depletion experiments and the
use of the MAP kinase kinase inhibitor PD98059 indicate that these two
MAP kinases are the major ets-2 kinases activated in response to
CSF-1/c-fms signaling. In the macrophage cell line RAW264, conditional
expression of raf kinase induced ets-2 expression and phosphorylation,
as well as uPA mRNA expression. Transient assays mapped ets/AP-1 response elements as critical for basal and CSF-1-stimulated uPA reporter gene activity. These results indicate that persistent activation of the raf/MAP kinase pathway by CSF-1 is necessary for both
ets-2 expression and posttranslational activation in macrophages.
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INTRODUCTION |
Macrophage colony-stimulating factor
1 (CSF-1) controls the proliferation and differentiation of cells of
the mononuclear phagocyte cell lineage. The actions of CSF-1 are
mediated through an integral membrane receptor tyrosine kinase, the
product of the c-fms proto-oncogene (22). As with
other tyrosine kinase receptors, ligand binding leads to c-fms
autophosphorylation, assembly of phosphotyrosine-dependent signaling
complexes, and the subsequent activation of signal transduction
pathways (25). Pathways controlled by CSF-1/c-fms include
phosphatidylinositol 3-kinase (23), JAK-STATs
(19), c-src-related kinases (6), and the ras
pathway (3, 7). The latter two pathways have been
demonstrated to be critical for the mitogenic action of CSF-1 (3,
6, 15).
CSF-1 stimulation results in the stable, persistent expression of
specific genes, for example, the urokinase plasminogen activator (uPA)
gene, in mature macrophages or in fibroblasts engineered to express
c-fms (3, 14, 27). The uPA gene encodes an extracellular protease involved in cellular migration in many cell types, including metastatic tumor cells (2) and macrophages (5,
27).
The uPA promoter contains regions conserved across species up to 8.2 kb
5' to the transcription start site (1, 5, 9). Within these
regions of homology, two compound ets/AP-1 growth factor- and
oncogene-responsive elements have been identified at 
2.4 and 6.9 kb
upstream of the transcription initiation site (1, 9, 27). In
transient transfections, oncoprotein ras collaborates with either ets-1
or ets-2 to superactivate the uPA promoter via the compound ets/AP-1
enhancer located at 2.6 kb relative to the transcription initiation
site (34). Collaboration between ras and exogenously
expressed ets factors depends on ras-dependent phosphorylation at
threonine residues Thr 38 and Thr 72 in ets-1 and ets-2, respectively
(34). The Thr 38 residue of ets-1 has been shown to be
phosphorylated in a CSF-1-dependent manner in NIH 3T3 cells that
exogenously express both ets-1 and c-fms (21). The
phosphorylation sites are contained in a 100-amino-acid domain that is
conserved between ets-1 and ets-2 and also in the Drosophila melanogaster protein pointed P2 (4, 20). The
conserved N-terminal domain of the ets factor pointed P2 has
been shown to be a nuclear target for ras signaling pathways critical
for differentiation of the R7 photoreceptor cell in
Drosophila, and thus defines a target for ras signaling
pathways that is conserved through evolution from flies to humans
(4, 20).
One well-characterized effector pathway activated by the ras-GTP
complex is the raf/MEK-1/mitogen-activated protein (MAP) kinase pathway
(16, 31). However, the exact identity of the ras effector
pathways that CSF-1/c-fms engage to persistently activate the uPA
promoter have not been defined. The ras/MAP kinase pathway has been
shown to activate TCF/elk-1 ets family transcription factors, but these
events occur early after growth factor stimulation and result in
regulation of immediate-early genes such as c-fos (reviewed
in reference 31). In PC-12 cells, activation of trkA has been shown to sustain activation of ras and MAP kinases p42 and p44
over several hours, leading to the proposition that the duration and
strength of the ras signal are the critical variables that distinguish
how cells interpret ras/MAP kinase signals generated by different
environmental stimuli (reviewed in reference 16).
In the present study, we present evidence for a signaling cascade
initiated by CSF-1/c-fms in either macrophages or heterologous cells
that ectopically express c-fms. This pathway involves stimulation of
the ras pathway, resulting in continuous activation of MAP kinases p42
and p44 and stable phosphorylation of ets-2 at threonine 72, events
that are correlated with the induction of uPA transcription by CSF-1.
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MATERIALS AND METHODS |
Cell culture and RNA analysis.
NIH 3T3 cells containing
genes expressing c-fms protein were grown in Dulbecco's modified
Eagle's medium (DMEM) with 10% fetal calf serum (FCS). Prior to
stimulation with CSF-1 (1 U = 0.01 ng) or platelet-derived growth
factor (PDGF, BB isoform; Upstate Biotechnology, Inc.), cells were
grown in DMEM with 0.1% FCS for 16 to 24 h. Cells were stimulated
with 104 U of CSF-1 per ml (27). RAW264 cells
were maintained in RPMI media containing heat-inactivated 5% FCS.
RAW264 cells expressing the estrogen receptor-active raf kinase fusion
protein were obtained from Julie Hambleton and Tony DeFranco and were
stimulated with 
-estradiol (10
7 M) as described
previously (11). The isolation of bone marrow-derived macrophages (BMMs) has been previously described (27), and
the cells were grown in RPMI media containing 10% FCS and
104 U of CSF-1 per ml. For the experiments described here,
BMMs were deprived of CSF-1 for 16 to 24 h and then restimulated
with 104 U of CSF-1 per ml as indicated in the figure
legends.
For experiments with the specific MEK-1 inhibitor PD98059,
serum-starved cells were treated with the drug at a final concentration of 50 µM (10) for 15 min prior to addition of CSF-1. The
drug was dissolved in dimethyl sulfoxide, and control cells were
treated with vehicle alone.
RNA isolation and Northern blotting were performed as previously
described (
14,
27).
Production of anti-phosphopeptide T72 ets-2 antibody and Western
blotting.
The peptides LPLL(p-T)PCS and LPLLTPCSKA corresponding
to amino acids 68 to 77 of human ets-2 were synthesized. The position of the phosphate at threonine 72 was confirmed by nuclear magnetic resonance. The phosphopeptide was coupled to keyhole limpet hemocyanin and used to immunize two New Zealand White rabbits. Collected serum was
pooled and passed over a column to which the nonphosphopeptide was
coupled, and material that did not bind to this column was collected
and passed over a phosphopeptide affinity column. Bound material was
eluted from this second column with glycine (pH 2) buffer, dialyzed
against phosphate-buffered saline and stored at 70°C before use.
Polyclonal, phosphorylation-independent ets-2 antibodies were produced
by immunization of rabbits with a recombinant ets-2 protein
corresponding to amino acid residues 60 to 167 [ets-2(60-167)].
Western blotting was performed with nitrocellulose membranes and the
ECG detection system (Amersham) as previously described
(
17,
34).
In-gel and MAP kinase assays.
The substrate for both in-gel
kinase and MAP kinase assays was the portion of human ets-2
corresponding to amino acid residues 60 to 167. This protein was
expressed as a six-histidine-tagged recombinant protein in
Escherichia coli K-12 by using the pET15b expression vector
system and was purified to >95% purity by nickel-Sepharose affinity
chromatography. Versions of the protein with either threonine or
alanine at position 72 were produced and purified.
The in-gel and MAP kinase assays have been described in detail
elsewhere (
17). For in-gel kinase assays, 100 µg of total
protein derived from BMMs or RAW264 cells was subjected to
electrophoresis
through a 12.5% acrylamide gel which had been
copolymerized with
500 µg of either the threonine 72 or alanine 72 versions of ets-2
protein per ml. After electrophoresis, the gel was
subjected to
a denaturation-renaturation procedure, the in-gel kinase
reaction
was performed, and the gel was subjected to autoradiography
for
24 h (
17).
An anti-MAP kinase antibody coupled to Sepharose beads was used for the
immune kinase experiments (Santa Cruz Biochemicals,
Santa Cruz,
Calif.). The immune complex obtained from incubation
of cell extracts
with this antibody was suspended in 30 µl of
kinase buffer (20 mM
HEPES [pH 7.2], 10 mM MgCl
2, 1 mM dithiothreitol,
0.5 mM
phenylmethylsulfonyl fluoride, 10 µg of leupeptin per ml,
10 µg of
aprotinin per ml, 1 mM orthovanadate, 1 mM EGTA, 10 mM
sodium fluoride,
1 mM tetrasodium pyrophosphate, 0.1 mM
-glycerophosphate)
that
contained 1 µg of the purified His-tagged ets-2 protein corresponding
to amino acids 60 to 167 and 5 µCi of [
-
32P]ATP.
After incubation at room temperature for 30 min, the reaction
was
terminated by addition of sodium dodecyl sulfate (SDS) sample
buffer
and boiling. The supernatant was run on denaturing gels
and analyzed by
autoradiography. In some experiments, as indicated
in the figure
legends, cold ATP was included in the kinase reaction.
For these
experiments, phosphorylation of threonine 72 in the
ets-2 substrate was
determined by Western blotting with the antiphosphopeptide
ets-2
antibody described above.
The jun kinase assays were performed with an influenza virus
hemagglutinin (HA)-tagged version of p55-JNK2 and glutathione
S-transferase (GST)-N-terminal c-jun recombinant proteins
(residues
1 to 79) as previously described (
13). Both
wild-type (S63/S73)
and mutated (S63/A73) versions of c-jun were
employed (
13).
Plasmids and transient transfections.
The parent plasmid for
the murine uPA promoter-luciferase reporters was pGL2-B (Promega). The
construction of the 8.2, 6.6, 6.6 
ets/AP-1, and 114
luciferase reporter plasmids has been previously described (1,
27). The 4.2, 2.6, and 2.2 reporters were derived from the
6.6 plasmid by digestion with HindIII, EcoRV, or BglII restriction sites located at
these positions in the 6.6 plasmid. The mouse c-fms cDNA
(3.7 kb) was placed into the simian virus 40 expression vector pECE
(27). The fms-pECE plasmid was obtained from
Changmin Chen (Centre for Molecular and Cellular Biology, University of
Queensland, Queensland, Australia). Electroporation of RAW264 cells and
determination of luciferase activity following transfection were
performed as previously described (27).
| |
RESULTS |
Recombinant ets-2 protein is a specific substrate for purified MAP
kinases p42 and p44 in vitro.
In work that depended on transient
transfection systems, we demonstrated that threonine 72 of ets-2 was
phosphorylated in a ras-dependent fashion (34). In an
attempt to define kinases that catalyze phosphorylation of this site in
ets-2 in vitro, an N-terminal region of ets-2 corresponding to the
region conserved in the Drosophila pointed P2 protein (amino
acids 60 to 167) was overexpressed as a six-histidine-tagged fusion
protein in bacteria. The fusion protein was subsequently purified and
used as a substrate for in vitro kinase reactions. Purified,
recombinant MAP kinase p44 could utilize this portion of ets-2 as a
substrate (Fig. 1A, lane 1). A
recombinant ets-2 protein containing the Ala 72 substitution was not
used as a substrate by MAP kinase p44 (Fig. 1A, lane 2). Furthermore,
phosphoamino acid analysis of the 32P-labeled threonine 72 ets-2(60-167) protein revealed exclusive phosphorylation at threonine
(data not shown). Identical results were obtained with purified MAP
kinase p42 (data not shown).
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FIG. 1.
MAP kinases p42 and p44 phosphorylate position threonine
72 of ets-2 in vitro. (A) Recombinant ets-2 proteins corresponding to
amino acids 60 to 167 that contained either threonine 72 or alanine 72 (200 ng of protein, lanes 1 and 2, respectively) were incubated with
[-32P]ATP and purified, activated MAP kinase p44 for
30 min and separated on an SDS-15% polyacrylamide gel. Autoradiography
was performed for 12 h. (B) In a parallel experiment, HA-tagged
JUNK2 was expressed in NIH 3T3 cells, immunoprecipitated, and used in
immune kinase assays with an N-terminal jun-GST fusion protein (amino
acids 1 to 79), a jun-GST protein with residues 63 and 73 mutated from
serine to alanine, or the threonine 72 version of ets-2(60-167) (200 ng of each protein, lanes 1 to 3, respectively). Autoradiography was
performed for 12 h. (C and D) Western blot of recombinant human
ets-2 proteins (amino acids 60 to 167) with threonine at position 72 (lanes 1 and 2) or alanine at position 72 (lanes 3 and 4). The proteins
(200 ng) were incubated with nonradioactive ATP in the absence (lanes 1 and 3) or presence (lanes 2 and 4) of activated MAP kinase p42 (Upstate
Biotech, Inc.) for 30 min. The blot was probed with affinity-purified
anti-phosphopeptide T72 antibody (C [see Materials and Methods]). The
same blot was stripped and probed with polyclonal antibody directed
against ets-2 residues 60 to 167 (D).
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In contrast, the MAP kinase family member p55-JNK2 (
13) did
not utilize the ets-2 recombinant protein (Fig.
1B lane 3) as
a
substrate under conditions where the N-terminal region of c-jun
(residues 1 to 79) could be phosphorylated in vitro (Fig.
1B,
lanes 1 and 2). In these experiments, the ets-2 protein was a
poorer substrate
than even the c-jun substrate that lacked the
major phosphorylation
sites at positions S63 and S73 (Fig.
1B,
lane 2), which was still
detectably phosphorylated at minor sites
by JNK2 as previously reported
(
13). Additionally, both MAP
kinase p38 (
32) and
the proline-directed kinase cdk4 were unable
to catalyze
phosphorylation of the ets-2 threonine 72 substrate
in vitro (data not
shown).
Production and characterization of antiserum specific for ets-2
phosphothreonine 72.
In order to directly measure the
phosphorylation of endogenous ets-2 at amino acid position threonine
72, an antibody that was specific for the phosphorylated threonine
residue was developed. For this purpose, the peptide PLL-pT-PCSKA
(corresponding to amino acids 69 to 77 of ets-2) was synthesized and
used to produce polyclonal rabbit serum. Following affinity
purification (see Materials and Methods), the specificity of the
antibody for detecting phosphothreonine 72 ets-2 in Western blotting
experiments was tested with recombinant ets-2 proteins corresponding to
amino acids 60 to 167.
For these experiments, the ets-2 region was incubated in vitro with
nonradioactive ATP and activated MAP kinase p44 (Fig.
1C). These
experiments showed that only wild-type threonine 72
protein which had
been incubated with the MAP kinase preparation
was recognized by the
antibody (lane two versus lane 1 in Fig.
1C). Proteins containing the
A72 substitution were not recognized
by the antibody whether MAP kinase
was present or absent (lanes
3 and 4). A second nondiscriminating
(i.e., phosphorylation independent)
antiserum directed against the
ets-2 N-terminal region (amino
acids 60 to 167) was also produced. When
the blot shown in Fig.
1C was stripped and reprobed with the second
antibody, equal loading
of the recombinant proteins could be
demonstrated (Fig.
1D). The
phosphopeptide-specific anti-peptide
antibody did not react with
blots that contained 10 µg of recombinant
unphosphorylated threonine
72 protein per lane, nor did it react with
other phosphoproteins,
for example, the N-terminal region of c-jun
(data not shown).
Persistent phosphorylation of ets-2 in response to CSF-1/c-fms
signaling in NIH 3T3 cells and in primary macrophages.
The
anti-phosphopeptide T72 ets-2 antibody was used to determine the
phosphorylation status of endogenous ets-2 in NIH 3T3 cells that
express the human c-fms receptor tyrosine kinase (23, 24).
Activation of c-fms tyrosine kinase activity by CSF-1 results in the
activation of ras signaling pathways and the persistent activation of
ras-responsive genes (3, 14, 27). For example, the
activation of uPA mRNA expression in these cells following CSF-1
stimulation was demonstrated in Fig. 2A.
In this experiment, Northern analysis reveals that uPA expression was
stimulated within 30 min following growth factor treatment and that the
expression of this mRNA persisted after 24 h of stimulation. In
contrast, stimulation of the same NIH 3T3 cell line with PDGF resulted
in only transient stimulation of uPA mRNA, with maximal stimulation after 30 min of PDGF treatment (Fig. 2A). We have previously reported this difference in the ability of CSF-1 and PDGF to stimulate the
expression of ras-responsive genes in NIH 3T3 cells (3). Thus, if ets-2 is involved in growth factor-induced activation of uPA
expression, it should be rapidly phosphorylated in response to CSF-1 or
PDGF stimulation, but in addition it should remain phosphorylated for
extended periods following CSF-1 treatment.
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FIG. 2.
Kinetics of uPA mRNA induction and phosphorylation of
ets-2 at threonine 72 in response to CSF-1/c-fms signaling in NIH 3T3
cells. (A) Northern blot of total RNA isolated from NIH 3T3 cells
expressing c-fms following stimulation with CSF-1 and PDGF (2 ng/ml)
for the times indicated (in hours) and probed with a mouse uPA probe
(upper panel) or a -actin probe (lower panel). (B) Nuclear protein
extracts were prepared from NIH 3T3 cells expressing c-fms following
stimulation with CSF-1 for the times indicated (in hours). Extracts
were run on a 10% SDS gel and Western blotted with the anti-pT72 ets-2
antibody (upper panel). The top arrow indicates the predicted location
of ets-2 (54 kDa), and the lower arrow indicates a second ets-2-related
band (45 kDa). The same samples in panel B were run on a second gel and
probed with a nondiscriminating ets-2 antibody directed against amino
acids 60 to 167 (bottom panel). (C) Nuclear protein extracts prepared
from NIH 3T3 cells stimulated with 2 ng of PDGF (BB isoform) per ml for
the times indicated (in hours) were analyzed by Western analysis with
the anti-pT72 antibody, as described above. Only the 54-kDa form of
ets-2 was detected (arrow). (D) NIH 3T3 cells expressing wild-type
c-fms Y809 (lanes 1 to 4) or the c-fms F809 protein (lanes 5 to 7) were
stimulated for increasing periods of time with CSF-1 as indicated (in
hours). Nuclear protein extracts were prepared and analyzed by
SDS-polyacrylamide gel electrophoresis (10% polyacrylamide gel)
followed by Western blotting with the anti-phosphopeptide T72 ets-2
antibody.
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Nuclear extracts were prepared from the NIH 3T3 cells expressing c-fms
following CSF-1 treatment for increasing periods of
time. These samples
were analyzed by Western blotting with the
anti-phosphopeptide T72
affinity-purified antibody (Fig.
2B).
Specific binding of the antibody
was not seen in the extracts
prepared from serum-starved cells.
However, the antibody detected
a major band of 54 kDa, the predicted
size for ets-2, within 30
min of CSF-1 treatment (Fig.
2B, upper panel,
upper arrow). This
band was observed throughout the CSF-1 time course
up to 24 h
after CSF-1 treatment. If antibody incubations were
performed
in the presence of the phosphopeptide used for immunization,
the
54-kDa band was not detected (data not shown). The nuclear samples
were analyzed with a nonphosphopeptide-selective ets-2 antibody
raised
against a recombinant ets-2 protein comprising amino acids
60 to 167 (Fig.
2B, lower panel). This antibody detected the same
54-kDa major
species in all samples, including the serum-starved
samples (Fig.
2B,
lower panel, upper arrow). The 54-kDa band was
not detected in
cytoplasmic extracts (data not shown).
In contrast to the results obtained with CSF-1, treatment of the same
NIH 3T3 cell line with PDGF resulted in a transient
stimulation of
ets-2 phosphorylation (Fig.
2D). The phosphorylation
of ets-2 was
maximal within 30 min following PDGF treatment and
was undetectable
after 8 to 12 h of treatment. The steady-state
levels of ets-2
protein, determined by using the nondiscriminating
antibody, were not
affected by PDGF treatment (data not shown).
Thus, ets-2 was
phosphorylated at position threonine 72 in a manner
consistent with the
kinetics of activation of uPA mRNA by either
CSF-1 or PDGF.
A mutation at an autophosphorylation site at tyrosine residue 809 in
the human c-fms (809Y
809F) protein selectively abrogates
the ability
of ligand-activated receptor to stimulate mitogenic
growth of NIH 3T3
cells and to stimulate expression of ras-responsive
genes like that
coding for uPA (
14,
27). The F809 receptor
also failed to
stimulate the conversion of ras to the GTP complex,
a conversion the
wild-type Y809 receptor efficiently carries out
(
20a). This
receptor failed to activate phosphorylation of ets-2
(Fig.
2D),
providing an additional correlation between ets-2 phosphorylation
and
receptor-dependent activation of persistent gene expression.
In addition to the major band migrating at the predicted size for
ets-2, a smaller, 45-kDa band was detected by both antibodies
used
(lower arrow in Fig.
2B and D). This band was especially
prominent
after 12 to 24 h of CSF-1 stimulation of cells. The
identity of
this cross-reacting species is under investigation,
but preliminary
data indicate that it may be derived by proteolysis
of the 54-kDa
protein species (data not shown).
The c-
fms gene is usually predominantly expressed in
monocytes and macrophages in adult mammals (
22), and we have
previously
implicated ets-2 in uPA activation in this cell type
(
27). In
BMMs deprived of CSF-1, the kinetics of uPA
induction were delayed
following restimulation with CSF-1 with respect
to the situation
observed in the artificial NIH 3T3 system. In BMMs,
uPA expression
was induced after 4 h and was maximal by 8 h
following stimulation
(Fig.
3A). When
nuclear extracts from BMMs stimulated with CSF-1
were analyzed, the
kinetics of ets-2 phosphorylation were also
found to be delayed
relative to those in the NIH 3T3 system, with
little of the
phosphothreonine 72 form of ets-2 seen until 4 to
8 h of CSF-1
treatment (Fig.
3B, upper panel, upper arrow). The
phosphothreonine 72 form of ets-2 was observed following 12 to
24 h of growth factor
stimulation and in cells continuously grown
in the presence of CSF-1
(data not shown). When these samples
were analyzed with
nondiscriminating antibody [anti-ets-2(60-167)
antibody], it was
observed that in contrast to NIH 3T3 cells,
ets-2 was not expressed in
CSF-1-deprived BMMs, but was detectable
after 4 h of CSF-1
treatment (Fig.
3B, lower panel, upper arrow).
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FIG. 3.
Kinetics of uPA mRNA induction and phosphorylation of
ets-2 at threonine 72 in response to CSF-1/c-fms signaling in primary
macrophages. (A) Northern blot of total RNA isolated from BMMs
following stimulation with CSF-1 (time in hours as indicated; *,
cells grown continually in CSF-1 without starvation) and probed with
mouse uPA (upper panel) or an 18S RNA probe (lower panel). (B) Nuclear
protein extracts were prepared from BMMs following stimulation with
CSF-1 for the times indicated. Extracts were run on a 10% SDS gel and
Western blotted with the anti-phosphopeptide T72 ets-2 antibody (upper
panel). The two arrows indicate the predicted location of ets-2 (54 kDa) and a second related 45-kDa band, as described above, while the
large arrowhead indicates the position of a 100-kDa cross-reacting
protein species. The same samples as those used in the upper panel were
analyzed in parallel with a nondiscriminating ets-2 antibody directed
against amino acids 60 to 167 (bottom panel). Lanes R and T contained
extracts prepared from RAW264 cells (negative control) or NIH 3T3 cells
that express c-fms (positive control), respectively, both treated with
CSF-1 for 24 h prior to extract preparation. Arrowheads indicate
the predicted position of ets-2 p54 and the related 45-kDa protein, as
described above.
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As in the NIH 3T3 cells, the faster-migrating 45-kDa cross-reactive
protein was again detected (Fig.
3B, lower arrows). In
addition, the
anti-phosphopeptide T72 antibody specifically cross-reacted
with a
protein with an apparent molecular mass of 100 kDa (Fig.
3B,
arrowhead). This 100-kDa species was induced within 1 h following
CSF-1 stimulation of BMMs and was detected at 8 h after
stimulation
as well. However, the 100-kDa protein was not recognized by
the
non-phosphopeptide ets-2 antibody (Fig.
3B, lower panel). The
nature of the 100-kDa species is currently under investigation.
The expression and phosphorylation of ets-2 in the macrophage cell line
RAW264 were also analyzed. CSF-1 does not stimulate
uPA transcription
in these cells (
27), and ets-2 expression
was not detected
with either phosphopeptide ets-2 or nondiscriminating
ets-2 antibodies,
regardless of whether CSF-1 was added to the
cell culture medium (Fig.
3B, lanes R). The anti-phosphopeptide
Thr 72 cross-reacting 100-kDa
band was also absent in RAW264 cells.
MAP kinase p42 and p44 activity correlates with ets-2
phosphorylation in BMMs and in NIH 3T3 cells.
Previous work has
indicated that CSF-1 stimulation of MAP kinase p42 and p44 activity in
macrophages is transient, with a peak of activity within 10 to 15 min
following growth factor stimulation (12), suggesting that
these kinases may not be the ets-2 kinase present in these cells. In
order to identify kinases capable of phosphorylating ets-2 in primary
macrophages, in-gel kinase assays were performed with the
ets-2(60-167) recombinant protein as a substrate (Fig.
4A, left panel, lanes 1 to 6). In
extracts derived from BMMs, the two major specific protein species
detected by this assay migrated with mobilities of 42 and 44 kDa.
Within 1 min of addition of CSF-1, the activity of these two kinases
was induced. In addition, the 42-kDa kinase remained active following 4 h of CSF-1 stimulation, indicating that activation of this
kinase was persistent in BMMs. In RAW264 cells treated with CSF-1,
there was five- to sevenfold-less induction of this ets-2 kinase
activity (Fig. 4A, lanes 7 to 12). When the Ala 72 form of the ets-2
pointed P2 domain was used as a substrate in this analysis,
the p42 and p44 bands were not detected (Fig. 4A, right panel). In
addition to the two specific bands, a number of constitutive
phosphorylated bands were detected. All of these were also observed
with the Ala 72 mutant ets-2 pointed domain (Fig. 4A, right
panel) and probably represent autophosphorylation of resident kinases.
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FIG. 4.
Kinetics of MAP kinase activation in response to CSF-1
stimulation in primary macrophages. (A) In-gel kinase assays with the
ets-2(60-167) threonine 72 (left panel), or alanine 72 (right panel)
protein as the substrate. BMMs were starved of CSF-1 for 16 h and
then stimulated with CSF-1 for 1, 5, 30, 60, and 240 min (lanes 1 to
6). RAW264 cells were stimulated with CSF-1 for the same times (lanes 7 to 12). For these experiments, the 12.5% acrylamide gel was
copolymerized with 500 µg of either the threonine 72 or alanine 72 versions of ets-2 protein per ml as indicated. Arrows indicate the
migration of the major kinase bands identified in the BMMs at 42 and 44 kDa, when threonine 72 protein is used as a substrate. These bands are
not seen in the gel containing the alanine 72 version of the protein.
(B) Immunoprecipitation kinase assays were performed with BMMs that had
been starved of CSF-1 for 16 h and then stimulated with CSF-1 for
the times indicated (in hours). MAP kinases p42 and p44 were
immunoprecipitated from 25 µg of whole-cell protein, and
incorporation of 32P into the ets-2 threonine 72 protein
substrate was measured in one-half of the sample following
electrophoresis in a 15% SDS gel (top panel). The other half of the
immune kinase assay was analyzed on a 10% SDS gel, and MAP kinase p42
and p44 were detected by Western blotting with a specific polyclonal
antibody (bottom panel).
|
|
In order to confirm that the specific protein species detected in the
in-gel kinase assay were MAP kinases p42 and p44, immune
kinase assays
were performed with BMM cell lysates with antibody
that specifically
recognizes these two MAP kinase species. Once
again, the ets-2
recombinant protein was utilized as a substrate.
These data were
consistent with those of the in-gel kinase assays,
demonstrating that
MAP kinase was detected within 30 min of CSF-1
stimulation and that
activity persisted up to 24 h following stimulation
(Fig.
4B,
upper panel). Analysis of these samples by Western blotting
with an
anti-MAPK kinase antibody revealed that the level of MAP
kinase did not
change during the CSF-1 time course (Fig.
4B, lower
panel). Consistent
with the in-gel kinase results, significant
MAP kinase activity was not
seen when such an assay was performed
with CSF-1-treated RAW264 cells
(data not shown).
The immune kinase assays as described above were repeated with lysates
prepared from NIH 3T3 cells that express c-fms (Fig.
5A). Little MAP kinase activity was
detected in CSF-1-starved
cells, but persistent activation of MAP
kinase activity was seen
from 30 min up to 24 h following CSF-1
treatment (Fig.
5A, left
panel). MAP kinase expression remains constant
over this time
course, as revealed by Western analysis with the same
MAP kinase-specific
antibody as that used above (Fig.
5A, right panel).
Stimulation
of F809-c-fms/NIH 3T3 cells with CSF-1 does not lead to
increased
MAP kinase activity (Fig.
5B), although Western analysis
indicated
that MAP kinase levels in these cells were comparable to
those
seen in the Y809-c-fms/NIH 3T3 cells (data not shown).
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|
FIG. 5.
Kinetics of MAP kinase activation in response to CSF-1
stimulation in c-fms/NIH 3T3 cells. (A) Immunoprecipitation kinase
assays were performed with extracts from NIH 3T3 cells expressing c-fms
and stimulated with CSF-1 for various amounts of time, as indicated (in
hours). MAP kinases were immunoprecipitated from 25 µg of whole-cell
lysates and incubated with recombinant ets-2 protein (amino acids 60 to
167) and cold ATP. One-half of the kinase assays were analyzed by
SDS-polyacrylamide gel electrophoresis (SDS-15% polyacrylamide gel)
followed by Western blotting with the anti-phosphopeptide T72 ets-2
antibody (left panel). For select samples (as indicated), one-half of
the kinase assay was analyzed with an SDS-10% polyacrylamide gel, and
MAP kinase p42 and p44 was detected by Western analysis (right panel).
(B) Immunoprecipitation-kinase assays were performed and analyzed as
described above with extracts from NIH 3T3 cells expressing either
wild-type c-fms (lanes 1 to 4) or the c-fms F809 mutant receptor (lanes
5 to 8). Samples were analyzed at the time points (in hours)
indicated.
|
|
MAP kinases p42 and p44 are the major ets kinases detected in
c-fms/NIH 3T3 cells.
To determine if kinases other than MAP
kinases p42 and p44 could be detected following CSF-1 stimulation, MAP
kinase p42 and p44 activity was depleted by five successive rounds of
immune precipitation from lysates prepared from CSF-1-stimulated
c-fms/NIH 3T3 cell lysates (Fig. 6A).
This analysis revealed that after four rounds of antibody treatment,
>95% of MAP kinase activity was removed from the cell lysates (lanes
3 to 7). At the same time, while ets kinase activity could be detected
in the supernatant recovered after the second round of
immunoprecipitation, no activity could be detected in the supernatant
that was recovered after the fourth round (lane 1 versus lane 2).
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|
FIG. 6.
MAP kinases p42 and p44 are the major ets-2 kinase in
c-fms/NIH 3T3 cells. (A) Immunodepletion of MAP kinase p42 and p44
activity in c-fms/NIH 3T3 cells stimulated for 24 h with CSF-1.
Five successive rounds of immunoprecipitation were performed to
completely deplete MAP kinase activity, and the precipitated kinase
activity was measured by 32P incorporation into the
ets-2(60-167) substrate detected after SDS-PAGE (15% gel, lanes 3-7,
respectively). The kinase activities remaining in the supernatant
following the second and fourth rounds of immunoprecipitation (lanes 1 and 2, respectively) were also measured by 32P
incorporation into the ets-2(60-167) substrate. (B) Inhibition of
ets-2 phosphorylation by the MEK-1 inhibitor PD98059. NIH 3T3 cells
that expressed c-fms were serum starved for 24 h (lane 1) and then
treated with CSF-1 and dimethyl sulfoxide (the carrier used for
PD98059) for 4 or 24 h (lanes 2 and 4, respectively) or with the
combination of CSF-1 and PD98059 for 4 of 24 h (lanes 3 and 5, respectively). Cells were also treated with PD98059 alone for 24 h
(lane 6). Nuclear extracts were prepared, and one-half of the extract
was analyzed by Western blotting with the anti-phosphopeptide ets-2
antibody. (C) The second half of the samples described above was
analyzed in parallel with the nondiscriminating ets-2 antibody. Lanes 1 to 6 contained the samples in the same order described above.
|
|
To further confirm that the raf/MEK-1/MAP kinase p42 and p44 pathway
was the major CSF-1-induced ets-2 kinase pathway, phosphorylation
of
ets-2 in the presence of the specific MEK-1 inhibitor PD98059
(
10) was determined with the anti-phosphopeptide T72 ets-2
antibody
(Fig.
6B). This experiment demonstrated that in fibroblasts
expressing
c-fms, PD98059 blocked ets-2 phosphorylation at both early
(Fig.
6B, lane 2 versus lane 3) and late (Fig.
6B, lane 4 versus lane
5) times following growth factor stimulation and also blocked
CSF-1
stimulation of uPA mRNA expression (data not shown). At
the same time,
ets-2 expression, as detected with the non-phosphopeptide-specific
antibodies, was not affected by drug treatment (Fig.
6C). The
same
experiments were attempted with primary mouse BMMs, but ets-2
expression could not be detected following treatment of cells
with both
CSF-1 and PD98059 (data not shown). Within hours of
exposure to the
drug PD98059, BMMs lose viability, as determined
by trypan blue dye
exclusion, making it difficult to determine
if the lack of ets-2
expression was a specific or general effect
of the drug.
Conditional expression of activated raf kinase in RAW264 cells
induces ets-2 expression and phosphorylation and uPA mRNA.
CSF-1
is not able to stimulate ets-2 expression or phosphorylation in RAW264
cells. In order to determine where the defect in CSF-1 signaling
occurs, RAW264 cells that express an estrogen-inducible form of raf
kinase were used to activate MAP kinases in a CSF-1-independent fashion
(11). We reasoned that such an analysis would reveal whether
the signaling defect lies downstream or upstream of raf kinase.
Following estrogen treatment, analysis of uPA mRNA levels indicated
that this gene was induced within 2 h and maximally stimulated
8 to 16 h after addition of estrogen (Fig.
7A, upper panel), after
correction for
RNA sample loading (lower panel,
-actin rehybridization
control).
Northern analysis also demonstrated that ets-2 mRNA
was induced in
these cells following stimulation of raf activity
(data not shown).
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FIG. 7.
Conditional expression of activated raf kinase in RAW264
cells induces ets-2 expression and phosphorylation. RAW264 cells that
express the estrogen receptor-raf fusion protein (11) were
treated with estrogen (107 M) for 2, 4, 8, or 16 h
(lanes 2 to 5, respectively) and compared to untreated cells (lane 1).
(A) RNA was prepared from the untreated and stimulated cells and
analyzed by Northern blotting with the uPA-specific probe (upper panel;
the arrow indicates the position of uPA mRNA). The blot was
rehybridized with an actin-specific probe to control for RNA loading
(lower panel). (B and C) Protein extracts were prepared from the
untreated and stimulated cells and analyzed by Western blotting with
the anti-ets-2 phosphopeptide T72 antibody (B) or the nondiscriminating
ets-2 antibody (C). Arrows indicate the positions of the p54 and p45
ets-2 proteins, respectively.
|
|
The expression and phosphorylation status of ets-2 protein were studied
by Western blotting (Fig.
7B and C). Use of the anti-phosphopeptide
T72
ets-2 antibody demonstrated that ets-2 was expressed and phosphorylated
following activation of raf kinase activity (Fig.
7B). As with
CSF-1
treatment of signaling-competent cells, both the p54 and
p45 forms of
ets-2 could be detected (see above). Use of the nondiscriminating
ets-2
antibody again demonstrated that both ets-2 bands were detected.
The
kinetics of ets-2 expression and phosphorylation paralleled
expression
of uPA mRNA.
In control experiments,
-estradiol had no effect on ets-2 or uPA
expression in either normal RAW264 cells or cells that contained
the
estrogen receptor vector lacking the raf kinase coding sequences
(reference
11 and data not shown).
cis element requirements for CSF-1 induction of the uPA
in RAW264 cells.
Given the results presented above, a possible
explanation for the failure of CSF-1 signaling to induce uPA
transcription in RAW264 cells is that the steady-state level of
receptor is insufficient to provide the signal required for sustained
activation of MAP kinases and subsequent phosphorylation of ets-2.
Consistent with this hypothesis, previous studies have shown that the
level of CSF-1 binding sites per cell and the level of c-fms mRNA are
lower in RAW264 cells than in BMMs (35) and that the
relative transcription of c-fms in run-on transcription
assays is lower (27).
To determine if transient overexpression of c-fms from a heterologous
promoter would rescue CSF-1 induction of uPA promoter
activity, RAW264
cells were cotransfected with a c-fms expression
plasmid and a uPA
reporter plasmid (Fig.
8A). Both CSF-1
and phorbol
ester were able to stimulate the uPA reporter, and the
effects
of the two agents were approximately additive (Fig.
8A). Cells
transfected with control expression plasmid lacking the c-fms
cDNA and
a uPA reporter responded only to phorbol ester, and there
was no
interaction between CSF-1 and phorbol ester (Fig.
8A).
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|
FIG. 8.
The ets/AP-1 enhancer is necessary for CSF-1 induction
of uPA reporter gene activity in RAW264 cells. (A) RAW264 cells were
transiently transfected with pGL2-uPA-6.6 with either the c-fms
expression plasmid or the empty parent plasmid, pECE. Where indicated,
104 U of CSF-1 per ml was added immediately after
electroporation, while 107 M phorbol myristate acetate
(PMA) was added after 6 h, and cells were harvested after 24 h. (B) RAW264 cells were transiently transfected with a series of uPA
promoter and enhancer mutations as represented in the first column. The
indicates the deletion of the ets/AP-1 element from the 6.6-kb
promoter. A c-fms expression plasmid was included with the various uPA
reporters in the transient transfection, cells were treated with or
without 104 U of CSF-1 per ml for 24 h, and the cell
lysates were assayed for luciferase activity. Luciferase activity is
presented as relative light units per microgram of protein. The results
of four experiments (A) or three experiments (B), each performed in
duplicate, are presented with bars representing the standard error.
|
|
The response of a series of uPA reporter plasmids to CSF-1/c-fms
activation was studied in order to determine the
cis
requirements
for cytokine activation (Fig.
8B). A construct containing
8.2
kb of information upstream of the mRNA initiation site had maximal
basal activity and was activated eightfold by CSF-1 in cells
cotransfected
with c-fms. The deletion from
8.2 to
6.6 kb, which
eliminates
the distal ets/AP-1 site at
6.9 kb (
9), reduced
both basal
and CSF-1/c-fms-induced promoter activities approximately
twofold.
Further deletions to
4.2 and
2.6 had no significant effect
on
either basal or CSF-1-induced activity of the uPA promoter. However,
a deletion to
2.3, which eliminates a second ets/AP-1 element
located
at
2.4 kb (
27), resulted in a further eightfold reduction
in both basal and CSF-1-induced promoter activity. Deletion of
the uPA
upstream region to
114 bp had no additional effect on
either basal
activity or the CSF-1/c-fms response. However, site-directed
deletion
of the conserved ets/AP-1 enhancer region located at
2.4 kb also
reduced both basal and CSF-1-stimulated activity
seven- to eightfold
(Fig.
8B,
6.6
). Thus, the ets/AP-1 site
located at
2.4 kb
distal to the uPA transcription initiation
site is necessary, although
not sufficient, for maximal CSF-1
induction of uPA promoter activity.
| |
DISCUSSION |
The data presented support a model in which CSF-1/c-fms receptor
ligation leads to prolonged activation of MAP kinases p42 and p44, to
sustained phosphorylation of ets-2 on residue threonine 72, and to
stable induction of uPA transcription. These results emphasize a basic
difference between macrophages and the fibroblast model for c-fms
signaling and reinforce the importance of studying c-fms action in the
biologically relevant monocyte/macrophage background (15).
In macrophages, the expression of ets-2 is part of the CSF-1
immediate-early response, and both expression of this gene and
activation of the factor by phosphorylation are mediated by the
raf/MAPK kinase signaling pathway. Future studies will be directed
toward understanding the regulation of the ets-2 gene in
macrophages. Activation of immediate-early MAP kinase targets such as
elk-1 (31, 32) or inactivation of repressors such as the ets
factor erf-1 (26) may be involved in the induction of the
ets-2 promoter.
The transient transfection studies with RAW264 cells support the
hypothesis that ets-2 is necessary for CSF-1 induction of the uPA
promoter. The ets/AP-1 element at 2.4 kb relative to the
transcription initiation site has been shown previously to mediate the
response to phorbol esters and oncoprotein ras in these cells (27,
34). Mutation of this site, along with the deletion of the region
containing a fibroblast growth factor-responsive ets/AP-1 site located
at 6.9 kb (9), resulted in a 90 to 95% decrease in both
basal and CSF-1-induced uPA promoter activity. Transcription of another
CSF-1-responsive gene in macrophages, the scavenger receptor, has also
been shown to be dependent on redundant promoter and enhancer elements
that include ets/AP-1-type elements (18, 33), indicating
that common mechanisms control the expression of CSF-1 target genes.
The dependence of the basal activity upon the ets/AP-1 elements was
unexpected given that the ets-2 protein is not detected in RAW264
cells. A potential explanation of the data lies in the observation that
RAW264 cells and primary macrophages are able to respond to
unmethylated CpG residues contained in the plasmid DNA used for the
transfections (28). The unmethylated DNA response is similar
to the response stimulated by bacterial lipopolysaccharide (LPS)
(28, 29), and both LPS and CpG DNA can mimic the ability of
CSF-1 to induce ets-2 expression and phosphorylation (29). Hence, the basal activity of the uPA promoter in transfected RAW264 cells may be interpreted as a response to plasmid DNA, which likely acts through the same ets/AP-1 elements.
The persistent activation of MAP kinases by CSF-1 in BMMs contrasts
with previous work where kinase activity was reported to decline
rapidly after an initial peak at 5 to 15 min following CSF-1 treatment
(12). The ets-2 substrate employed in the present studies
may be a more efficient monitor of specific MAP kinase activity than
other substrates commonly used. The use of the ets-2 pointed
P2 domain as a substrate has the additional advantage that it
distinguishes activation of p42 and p44 from the activation of other
proline-directed kinases, which were not able to phosphorylate this
substrate. This is in contrast to the ets factor elk-1 and related
proteins which are phosphorylated by multiple MAP kinase family
members, including MAP kinase p42/p44, JNK, and p38 (31, 32).
How is the persistent signal in response to CSF-1 maintained? The
results obtained with RAW264 cells suggest an answer to this question.
In RAW264 cells, c-fms expression is likely below a threshold that
allows persistent engagement of the ras/MAP kinase pathway and
activation of the uPA promoter, and transient overexpression of c-fms
rescues the signaling defect. In primary macrophages, CSF-1 and its
receptor are rapidly internalized and degraded following CSF-1 binding
so that there is a cycle of receptor-mediated ligand degradation
(reviewed in reference 22). Thus, the steady-state level of c-fms could determine whether a transient or persistent signal
is engaged in response to CSF-1. Similarly, the failure of PDGF to
stimulate persistent phosphorylation of ets-2 in NIH 3T3 cells may
reflect rapid turnover of the PDGF receptor with respect to c-fms
following growth factor treatment. Such arguments are consistent with
results obtained in other systems, for example, increasing steady-state
levels of the epidermal growth factor or insulin receptors in PC-12
cells results in prolonged activation of the ras/MAP kinase pathway and
neuronal differentiation of this cell type (8, 30).
In conclusion, the present studies indicate that CSF-1 action involves
the continual activation of MAP kinase activity, leading to
transcription factor phosphorylation and selective activation of gene
transcription. Studies of CSF-1 signaling provide one paradigm for
understanding how tyrosine kinase receptors trigger persistent
signaling pathways as well as the biological consequences of such
prolonged signaling events.
| |
ACKNOWLEDGMENTS |
L.F.F. and M.L.M. contributed equally to this work.
We thank Michael Karin for the HA-JUNK2 expression vector and GST
vectors to express c-jun N-terminal peptides and Julie Hambleton and
Tony DeFranco for providing the estrogen receptor-raf/RAW264 cells.
This work was supported by NIH grant CA-53271 (M.C.O.) and by the
National Health and Medical Research Council of Australia (D.A.H.). The
DNAX Research Institute is supported by the Schering Plough
Corporation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Genetics, 484 West Twelfth Ave., The Ohio State University, Columbus, OH 43210. Phone: (614) 688-3824. Fax: (614) 292-4466. E-mail:
ostrowski.4{at}osu.edu.
| |
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