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Blood, Vol. 93 No. 2 (January 15), 1999:
pp. 537-553
Synergistic Activation of Mitogen-Activated Protein Kinase by Cyclic
AMP and Myeloid Growth Factors Opposes Cyclic AMP's Growth-Inhibitory
Effects
By
Angel Wai-mun Lee
From the Department of Biochemistry and Molecular Biophysics,
Washington University Medical School, St Louis, MO.
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ABSTRACT |
Colony-stimulating factors (CSFs) promote the proliferation,
differentiation, commitment, and survival of myeloid progenitors, whereas cyclic AMP (cAMP)-mediated signals frequently induce their growth arrest and apoptosis. The ERK/mitogen-activated protein kinase
(MAPK) pathway is a target for both CSFs and cAMP. We investigated how
costimulation by cAMP and colony-stimulating factor-1 (CSF-1) or
interleukin-3 (IL-3) modulates MAPK in the myeloid progenitor cell
line, 32D. cAMP dramatically increased ERK activity in the presence of
CSF-1 or IL-3. IL-3 also synergized with cAMP to activate ERK in
another myeloid cell line, FDC-P1. The increase in ERK activity was
transmitted to a downstream target, p90rsk. cAMP treatment
of 32D cells transfected with oncogenic Ras was found to recapitulate
the superactivation of ERK seen with cAMP and CSF-1 or IL-3. ERK
activation in the presence of cAMP did not appear to involve any of the
Raf isoforms and was blocked by expression of dominant-negative MEK1 or
treatment with a MEK inhibitor, PD98059. Although cAMP had an overall
inhibitory effect on CSF-1-mediated proliferation and survival, the
inhibition was markedly increased if ERK activation was blocked by
PD98059. These findings suggest that upregulation of the ERK pathway is
one mechanism induced by CSF-1 and IL-3 to protect myeloid progenitors
from the growth-suppressive and apoptosis-inducing effects of cAMP elevations.
© 1999 by The American Society of Hematology.
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INTRODUCTION |
HEMATOPOIESIS, the formation and
functional activation of blood cells, is controlled by dynamic and
precisely coordinated events, many of which are still poorly
understood. Central to this regulatory process in mammals are the
hematopoietic colony-stimulating factors (CSFs), critical mediators of
cellular proliferation, differentiation commitment, survival, and
activation of mature cell functions. Cells of the myeloid lineage have
been most clearly shown to be those affected by CSFs.1 The
earliest cells committed to differentiate along this lineage are the
granulocyte-macrophage (myeloid) progenitors. Myeloid progenitors and
their progeny can respond to several CSFs1; the relative
importance of each factor may vary depending on the differentiation
status of the cell and on the availability of the factor from the
microenvironment. The macrophage CSF, CSF-1, is a factor specifically
responsible for maintenance of monocyte/macrophage populations. Its
receptor, CSF-1R, is a member of the tyrosine kinase family of growth
factor receptors.2,3 CSF-1R is expressed on the majority of
murine bone marrow cells with blast morphology (myeloid progenitors); its expression then becomes more restricted but not exclusively to
those progeny further committed to differentiate along the monocyte/macrophage series.4 That CSF-1 is an important
growth factor for these cells is illustrated by the finding of a
macrophage deficiency in the op/op mouse lacking functional
CSF-1,5 with the deficiency being severe in certain
macrophage populations, including that in the blood. op/op mice
also show a significant reduction in hematopoietic stem cells and
progenitors,5 indicating that CSF-1 acts on early precursor
cells as well as on the more mature monocytes and macrophages. In
agreement with the notion that CSF-1 can act on early precursors, CSF-1
is known to cooperate with interleukin-1 (IL-1) to dramatically
stimulate proliferation of multipotent progenitor cells more primitive
than those that normally respond to CSF-1.6
Cyclic AMP (cAMP) is another important modulator of myeloid cell
proliferation. cAMP is produced when specific serpentine receptors
coupled to adenylate cyclase are activated. Some examples of such
receptors expressed on myeloid cells are  -adrenergic receptors7 and receptors for prostaglandin E2
(PGE2)8 and the chemokine, macrophage
inflammatory protein-1 (MIP-1).9 The
bone marrow is densely innervated by adrenergic fibers,10 whereas PGE2 and MIP-1 are both secreted by
monocytes/macrophages.11,12 Although PGE2 and
MIP-1 binding can induce other mediators as well, their effects on
growth can be mimicked in some cells by directly increasing
intracellular cAMP levels or by activating the cAMP-dependent protein
kinase, protein kinase A (PKA).9,13 cAMP inhibits
CSF-1-induced proliferation of functionally differentiated macrophages,14,15 but the effect of cAMP and CSF-1
costimulation in myeloid progenitors is not known.
Maintenance of hematopoietic homeostasis requires the ability to
respond dynamically to a wide range of environmental stresses, such as
infection and trauma, as well as normal growth and development. Progenitor cells must be able to appropriately integrate signals, both
positive and negative, from multiple sources. The ability of cAMP to
modulate growth factor-stimulated proliferation/differentiation is
traced in some cell types to its effects on the extracellular signal
regulated kinase (ERK)/mitogen-activated protein kinase (MAPK) module.
This module consists of three kinases that act sequentially: an MAPKKK
(Raf isoforms), an MAPKK (MEK1/2), and an MAPK (ERK1/2).16
ERKs phosphorylate cytosolic proteins, eg, p90rsk17 and
MAPKAP,18 and also translocate to the nucleus to
phosphorylate transcriptional factors, eg, TCF/Elk.19 cAMP
binds to and activates PKA, which then phosphorylates Raf-1, leading to
a reduction of the latter's affinity for Ras-GTP and inhibition of its
enzymatic activity.20 In diverse cell types such as NIH 3T3
cells,21 arterial smooth muscle cells,22 and
cortical astrocytes,23 inhibition of Raf-1 by PKA leads to
an inhibition of growth factor-stimulated ERK activity that can
correlate with growth suppression. On the other hand, cAMP acting
through the Rap1/B-Raf pathway activates ERK and induces
differentiation of PC12 cells.24-27
Despite their manifest importance, many questions remain open on the
signaling mechanisms used by CSF-1 in myeloid progenitors. In part,
this reflects the difficulty of obtaining from the bone marrow,
sufficient numbers of pure populations of CSF-1R-bearing cells at the
same stage of precursor development, a prerequisite for biochemical
studies. To overcome this problem, our studies of CSF-1-dependent
signaling events in myeloid precursors have used the 32Dcl23 cell line
transfected with the murine CSF-1R.28-30 32Dcl23 is a
nonleukemic murine myeloid progenitor cell line that self-renews in the
presence of IL-3. They lack endogenous CSF-1R, but, when transduced
with an exogenous CSF-1R, will use CSF-1 as a growth and survival
factor.28 Support for a proliferative rather than a
differentiative role of CSF-1R in myeloid progenitors comes from
studies in which infection of blast cells harvested from
5-flurouracil-treated mice with a CSF-1R retrovirus enhanced their
proliferation and not their differentiation capacity.31 A
survival role for CSF-1R is implicated by the observation that op/op mice engineered to express the bcl-2 transgene in myeloid progenitors showed marked restoration of monocytopoiesis in the bone
marrow.32 32D/CSF-1R cells therefore represent a relevant in vitro model to study the proliferative and survival function of
CSF-1 in myeloid progenitors and have the additional advantage of being
a homogeneous cell population compared with bone marrow blast cells.
The purpose of the present study was to examine in a myeloid cell line
transduced with the murine CSF-1 receptor how cAMP and myeloid growth
factor costimulation affects activation of ERK, a common target for
both agents. Because serpentine receptors frequently activate multiple
G-proteins that couple to different intracellular signaling pathways,
we have used pharmacological agents to directly assess the role of the
cAMP second messenger system. cAMP synergized with CSF-1 (acting on a
tyrosine kinase receptor) or IL-3 (acting on a cytokine receptor) to
greatly increase ERK activity. Despite the marked upregulation of ERK
activity, cAMP still antagonized growth factor-dependent mitogenesis
and cell survival. However, blockage of ERK activation in 32D cells accelerated the growth inhibition and apoptosis induced by cAMP. These
results indicate that the ability of growth factors to cooperate with
cAMP and enhance ERK activation protected 32D cells from the
antiproliferative and proapoptotic effects mediated by cAMP. The
implications of these findings in hematopoietic homeostasis are
discussed.
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MATERIALS AND METHODS |
Antibodies and reagents.
Polyclonal antibodies against ERK2 (sc-154), Raf-1 (sc-133), B-Raf
(sc-166 and competing peptide), A-Raf (sc-408 and competing peptide),
and p90rsk (RSK1, sc-231) were from Santa Cruz
Biotechnology (Santa Cruz, CA). Monoclonal antibodies were
from the following sources: anti-Raf-1, MEK1, MEK2, ERK1, ERK2, ERK3,
pan ERK, PY20 antiphosphotyrosine antibody (Transduction Laboratories,
Lexington, KY), ERK1/2 (Zymed, San Francisco, CA), Y13-258 and Ab-4
anti-Ras antibodies (Oncogene Research, Cambridge, MA),
and antihemagglutinin antibody (HA.11, BAbCo, Richmond, CA). Secondary
antibodies were from GIBCO BRL (Gaithersburg, MD) or
Zymed. Recombinant human CSF-1 was a gift from Genetics Institute
(Cambridge, MA), recombinant murine IL-3 was from Becton Dickinson
(Bedford, MA), protein A and protein G sepharose were from
Zymed, S6 peptide (RRRLSSLRA) was from Upstate Biotechnology (Lake
Placid, NY), myelin basic protein (MBP) and cell culture
media were from GIBCO BRL, PD98059 was from Calbiochem (La Jolla,
CA), and all other reagents were from Sigma (St Louis, MO).
Plasmids and plasmid construction.
The murine CSF-1R cDNA described previously28 was cloned
into the mammalian expression vector pCEN/MPSV to generate plasmid pCEN/MSPV-CSF-1R. The parental pCEN vector from John Majors (Washington University Medical School, St Louis, MO) was modified to pCEN/MPSV, which contains the enhancer/promoter sequences from the
myeloproliferative sarcoma virus so as to extend host
range.29 The 61LRas fragment was released from pZIP-RasH61L
(a gift of Channing Der, University of North Carolina, Chapel Hill,
NC) and inserted into the pcDNAIneo expression vector
(Invitrogen, Carlsbad, CA). pCMV5-MEK1(S218A, S222A) was
from Kun-Liang Guan (University of Michigan, Ann Arbor, MI). To avoid potential interference from the
Epstein-Barr virus sequences present in pCEP4-HA-tagged ERK2 (a gift
of Melanie Cobb, University of Texas, Southwestern,
Dallas, TX), they were deleted from HA-ERK2/pCEP4 to generate
HA-ERK2/pCEP4 . Bacterial expression plasmids encoding His-tagged
wild-type MAPK, kinase-dead (KD) MAPK, and KD-MEK were from Gary
Johnson (National Jewish Center for Immunology and Respiratory
Medicine, Denver, CO) and His-tagged proteins were
purified as described.33
Cell culture and treatments.
FDC-P134 and 32Dcl2335 are murine nonleukemic
myeloid precursor cell lines dependent on IL-3 for growth and survival. FDC-P1 can also use granulocyte-macrophage growth factor
(granulocyte-macrophage colony-stimulating factor [GM-CSF]) instead
of IL-3. The FDC-P1 cell line was obtained from Larry Rohrschneider
(Fred Hutchinson Cancer Center, Seattle, WA) and
maintained in Dulbecco's modified Eagle medium (DMEM)
with 10% fetal bovine serum (FBS) and 5% WEHI-CM (conditioned medium)
as a source of murine IL-3; the maintenance of 32D cells has been
described previously.29 The rat pheochromocytoma cell line,
PC12,36 was obtained from the American Type Culture Collection (Manassas, VA) and maintained in F-12K medium
supplemented with 15% horse serum and 2.5% FBS. For kinase assays,
cycling cells were rinsed twice in Hanks' Buffered Salt Solution
(HBSS) before starving for 2 hours in serum-free medium whose
components were as described.37 Cells were then treated as
indicated in the figure legends. In cases in which stock solutions of
test agents (forskolin, 3-isobutyl-1-methylxanthine [IBMX], PD98059) were in dimethyl sulfoxide (DMSO), an equal volume of DMSO was added to
control cells. Optimal doses of CSF-1 (1 to 10 nmol/L) and IL-3 (50-100 U/mL) were used in all experiments.
Transfections.
To establish stable cell lines expressing CSF-1R, 32D cells were
electroporated with 20 µg of pCEN/MPSV-CSF-1R plasmid using a Gene
pulser (Bio-Rad, Hercules, CA). Forty-eight hours later, transfected cells were placed in complete medium containing 1 mg/mL of
G418. Drug-resistant mass populations were selected over 1 week, and
individual clones were isolated by limiting dilution and screened for
surface expression of CSF-1R by binding to 125I-CSF-1 as
described previously.28 Two clones, WT8 and WT10, were
selected for further study. Efficiency of transient transfections was
determined using 5 to 10 µg of a pcDNA1Neo construct expressing -galactosidase. Cells (1 × 107) were
electroporated at 280 V, 960 µF. Similar to transfection efficiencies
reported for other hematopoietic cells,38,39 we found that
20% to 22% of viable cells stained positive with X-gal 24 hours after
transfection. Higher transfection efficiencies could be achieved with
larger amounts of DNA but at the expense of increased cell death.
Accordingly, a tagged ERK2 construct (HA-ERK) was used as a reporter in
transient cotransfections. The total transfected DNA was kept constant
with pcDNA1Neo. Twenty-four hours after electroporation, dead cells
were removed by spinning through a Ficoll cushion (Organon
Teknika, Durham, NC), rinsed in HBSS, and placed in
serum-free medium. Cells were treated as described above.
Immunoprecipitation and kinase assays.
After treatment, cells were rinsed in HBSS before lysis in ice-cold
buffer containing 20 mmol/L Tris, pH 7.5, 2 mmol/L EDTA, 50 mmol/L
NaCl, 10 mmol/L sodium pyrophosphate, 50 mmol/L NaF, 1% (vol/vol)
Triton X-100, 0.5% (wt/vol) sodium deoxycholate, 50 mmol/L
-glycerophosphate, and 10% (vol/vol) glycerol containing 10 µg/mL
aprotinin, 10 µg/mL leupeptin, 1 µg/mL pepstatin A, 1 mmol/L
Na3VO4, 1 mmol/L benzamidine, 1 mmol/L
phenylmethylsulfonyl fluoride, and 1 mmol/L dithiothreitol (DTT).
Insoluble material was pelleted by centrifugation and the protein
content of the lysate determined by the Bio-Rad protein assay. For ERK
and MEK assays, lysates were incubated with the appropriate antibody
and protein A sepharose for 4 hours. In cotransfection experiments with
HA-ERK2, HA-ERK2 expression was first quantitated by Western blotting
and the amount of lysate used for each condition adjusted to contain
equivalent levels of HA-ERK2. ERK or HA immunoprecipitates were washed
twice with buffer A (10 mmol/L Tris, pH 7.4, 1% Nonidet P-4, 0.5%
deoxycholate, 0.1 mol/L NaCl, 1 mmol/L EDTA, 1 mmol/L DTT, 0.2 mmol/L
Na3VO4), twice with buffer B (10 mmol/L Tris pH 7.4, 0.1 % Nonidet P-40, 1 mol/L NaCl, 1 mmol/L EDTA, 1 mmol/L DTT,
0.2 mmol/L Na3VO4), once with buffer C (50 mmol/L Tris, pH 7.4, 0.15 mol/L NaCl), and once with kinase buffer (20 mmol/L HEPES, pH 7.4, 10 mmol/L MgCl2, 1 mmol/L
MnCl2, 1 mmol/L EGTA, 0.03% Brij35, 2 mmol/L DTT, 0.2 mmol/L Na3VO4). Immunoprecipitates were
resuspended in kinase buffer containing 10 µmol/L ATP, 5 µCi
[32P] ATP (3,000 Ci/mmole; NEN, Boston,
MA), 20 µg/mL aprotinin, 5.35 µmol/L protein kinase A
inhibitor peptide (PKI), and 0.25 mg/mL MBP and incubated at 30°C
for 15 minutes. The reaction was terminated by boiling in Laemmli
sample buffer and the products were analyzed by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). For MEK assays,
immunoprecipitates were washed twice in lysis buffer, twice in lithium
chloride buffer (0.1 mol/L Tris, pH 7.4, 0.5 mol/L LiCl), and once in
kinase buffer (25 mmol/L HEPES, pH 7.4, 25 mmol/L -glycerophosphate,
pH 7.5, 10 mmol/L MgCl2, 1 mmol/L MnCl2, 0.5 mmol/L EGTA, 0.03% Brij35, 1 mmol/L DTT, 0.2 mmol/L
Na3VO4) before resuspending in kinase buffer
containing 200 to 400 ng recombinant KD-MAPK as substrate and other
components as described above. The reaction was continued for 15 minutes at 30°C and processed as described above. ERK and MEK assay
conditions were chosen such that substrate phosphorylation was in the
linear range with respect to lysate amount and incubation time. For
MEK-coupled assays, immunoprecipitates were first incubated for 30 minutes at 30°C in kinase buffer containing 100 µmol/L ATP, 20 µg/mL aprotinin, and 150 ng of recombinant wild-type MAPK followed by
the addition of 5 µCi [32P]ATP and 0.25 mg/mL MBP
and further incubation for 15 minutes. For Raf assays, 1 mg of cell
lysate was immunoprecipitated with 2 µg of antibody and the
immunoprecipitates were washed and kinase activity was measured as
described for MEK, except that 400 ng of recombinant KD-MEK was used as
substrate. When a competing peptide was used to test the specificity of
A-Raf or B-Raf immunoprecipitations, the antibody and peptide were
allowed to incubate for 30 minutes before the addition of lysates.
Gels were Coomassie Blue-stained to locate substrate bands, dried, and
subjected to autoradiography. To quantitate substrate phosphorylation,
the appropriate bands were either cut out and Cerenkov-counted or
quantitated using the PhosphorImager and ImageQuant software (Molecular
Dynamics, Sunnyvale, CA).
For p90rsk assays, immunoprecipitates were washed twice in
lysis buffer, once in Tris-buffered saline, and twice in kinase buffer. Activity of p90rsk was determined by measuring
32P incorporation into S6 peptide in a reaction mixture
containing kinase buffer (25 mmol/L HEPES, pH 7.4, 25 mmol/L
-glycerophosphate, 1 mmol/L EGTA, 0.5 mmol/L DTT, 10 mmol/L
MgCl2), 250 µmol/L S6 peptide, 6 µmol/L PKI, 50 µmol/L ATP, and 6 µCi [32P]ATP. Incubation was for
15 minutes at 30°C, and the reaction supernatant was spotted onto
P81 paper, rinsed four times in 0.5% phosphoric acid, dried in
acetone, and counted.
Western blotting.
After boiling in Laemmli sample buffer, cell lysates (20 µg) or
immunoprecipitates were fractionated by SDS-PAGE and transferred to
Immobilon-P (Millipore, Bedford, MA) membranes. Membranes
were immunoblotted with primary antibodies at the recommended
dilutions, incubated with horseradish peroxidase-conjugated secondary
antibodies, and developed by enhanced chemiluminescence (Amersham,
Arlington Heights, IL). In some cases, autoradiography
images were scanned with an Epson ES-1000C scanner and transparency
module (Epson, Torrance, CA) using Adobe Photoshop version 3 software (Mountain View, CA). Their intensities were
quantitated using NIH Image 1.6 software (provided by the
Research Services Branch, NIMH, National Institutes of Health,
Bethesda, MD) without further manipulation of the images.
Fluorescence-activated cell sorting (FACS) analysis.
To examine Ras expression in transiently transfected cells, 32D/CSF-1R
cells were harvested 24 hours after electroporation, fixed in 0.5%
formaldehyde, and permeabilized with methanol before staining with 20 µg/mL of Y13-258 anti-Ras antibody and a phycoerythrin-conjugated secondary antibody. FACS analysis was performed by the Washington University Pathology Department. As a negative control, cells were
stained with an isotype-controlled antibody, anti-CD4.
Cell cycle analysis, proliferation, and apoptosis assays.
Proliferation was determined either by the MTS
[3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium] assay or by cell counts. For the MTS assay, 2 × 104
cells were aliquoted per well of a 96-well dish in a total volume of
100 µL RPMI with 10% FBS and various test reagents. Each condition was performed in duplicate. After 48 hours, MTS and phenazine methosulfate (PMS) were added according to the manufacturer's protocol
(Promega CellTiter 96 Aqueous kit; Promega, Madison, WI).
Cells were returned to the incubator for another 2 to 3 hours. The
tetrazolium is reduced by metabolically active cells into formazan
products, which are detected at 490 nm in a plate reader. For cell
counts, cells were seeded at 5 × 104/mL in the
various test media and cell numbers were determined daily in duplicate
by counting with a hemacytometer. Viability was assessed by Trypan Blue
dye exclusion. Apoptosis was detected using the method of Kinoshita et
al.40 Cells were seeded at a density of 2 × 105/mL in 8 mL of various test media. Twenty-four hours
later, they were harvested and lysed in 600 µL of lysis buffer (10 mmol/L Tris, pH 7.5, 10 mmol/L EDTA, 0.2% Triton X-100). Nuclei and
other cellular debris were removed by centrifugation and the
supernatant subjected to three rounds of extraction with
phenol:chloroform (1:1). Low molecular weight chromosomal DNA was
precipitated and dissolved in 10 mmol/L Tris, pH 8, 1 mmol/L EDTA, and
RNA digested by incubation with 50 µg/mL RNAase A for 3 hours at
37°C. An equal volume of each sample was then loaded onto 1.5%
agarose gels and DNA laddering was visualized by ethidium bromide
staining.
| |
RESULTS |
cAMP inhibits CSF-1 and IL-3-stimulated growth of a myeloid progenitor
cell line.
A cell line, 32Dcl23, which is differentiated to the myeloid progenitor
stage but before the onset of CSF-1R expression, was transfected by
electroporation with a mammalian expression vector encoding the murine
CSF-1R cDNA. Two clones, WT8 and WT10, were selected for further study.
By Scatchard analysis, WT8 and WT10 expressed 4.5 × 104 and 1 × 104 receptors/cell,
respectively. For each clone, maximal proliferative response as
determined by cell counting was induced by 1 nmol/L CSF-1 in the
presence of serum, comparable to that elicited by 10% WEHI-CM, a
source of murine IL-3. Data presented in the figures of this report
were derived from WT8, but results have been confirmed with WT10 in
most instances. Other investigators have reported that transduction of
CSF-1R into a 32D subclone, 32Dcl3 (G), permits partial monocytic
differentiation in the presence of CSF-1.41,42 Our clones
(at least 3 have been analyzed in detail) have been monitored for 7 days in culture for signs of adhesion, morphological changes, and the
acquisition of monocytic markers such as Mac-1 and Fc in response to
CSF-1 (A.W.L., unpublished observations), and none has
been observed. The basis for the difference is likely to be due to
differences in lineage commitment, because 32Dcl3 (G) is already
committed to differentiate along the myelomonocytic lineage and
undergoes granulocyte colony-stimulating factor (G-CSF)-dependent terminal differentiation, whereas 32Dcl23 does not.43
cAMP elevations are frequently but not universally linked to growth
suppression. We first determined if the 32D/CSF-1R cell line is
appropriate for investigations of the growth-inhibitory effects of
cAMP. CSF-1- or IL-3-stimulated mitogenesis of 32D/CSF-1R cells was
examined in the presence of varying concentrations of two agents known
to activate PKA, which is the primary effector of cAMP in eukaryotic
cells. They are forskolin, which directly stimulates adenylate cyclase
to produce cAMP, and dibutyrl cAMP (btcAMP), a cell-permeable cAMP
analog. Mitogenesis was assayed by the colorimetric MTS assay and the
results are shown for WT8 in Fig 1. Very
similar results were obtained for WT10. Both btcAMP and forskolin
exerted a dose-dependent inhibition of CSF-1- and IL-3-dependent
mitogenesis, with IL-3 being somewhat more resistant to the
antiproliferative effects of btcAMP (ED50 is 0.35 mmol/L for CSF-1 and 0.8 mmol/L for IL-3).
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| Fig 1.
cAMP elevations inhibit CSF-1- and IL-3-stimulated
mitogenesis in 32D/CSF-1R myeloid cells. Exponentially growing cells
were seeded into RPMI, 10% FBS with either 5 nmol/L CSF-1 or 100 U/mL
of murine recombinant IL-3 and the indicated doses of btcAMP (left
panel) or forskolin (right panel). Forty-eight hours later, mitogenesis
was determined by the colorimetric assay as described in Materials and
Methods. Results are shown as a percentage of the absorbance at 490 nm
obtained for cells growing in IL-3 and represent the mean ± SE of
duplicate samples.
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cAMP and CSF-1 costimulation synergistically activate ERK.
cAMP is known to inhibit growth factor-stimulation of the Ras/MAPK
pathway in a variety of cell types. We investigated if cAMP's growth
inhibitory effects in 32D/CSF-1R cells could be a consequence of
inhibition of CSF-1-stimulated ERK activity. Western blotting with
different anti-ERK antibodies indicated p42ERK2 to be the
predominant ERK species and MEK1 and MEK2 antibodies both recognized
46-kD proteins (data not shown). To measure ERK and MEK activities,
cells were starved in serum-free medium for 2 hours before CSF-1
addition. CSF-1 stimulated a robust increase in the activities of both
kinases (Fig 2A and E): on
average, ERK and MEK1 activities were increased by 15.4- ± 3.1-fold
(SE; n = 16) and 4.7- ± 0.8-fold (SE; n = 13), respectively, over
untreated cells after 4 minutes of CSF-1 stimulation.
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| Fig 2.
cAMP cooperates with CSF-1 to synergistically
activate ERK/MAPK. 32D/CSF-1R cells were starved in serum-free media
for 2 hours. Where indicated, 50 µmol/L forskolin (forsk) and 0.5 mmol/L IBMX or 1 mmol/L btcAMP were added during the last 20 minutes of
the incubation or as indicated and then stimulated with or without
CSF-1 for 4 minutes or as indicated at 37°C. Immune complex kinase
assays were performed on lysates normalized for protein content. Fold
refers to increase in substrate phosphorylation relative to that in
untreated cells. (A) ERK2 was immunoprecipitated and activity measured
in an in vitro kinase assay with MBP as a substrate. The left panel
shows that similar results were obtained with either a 10- or 30-minute
pretreatment period with forskolin/IBMX and with btcAMP. The right
panel shows that forskolin/IBMX pretreatment increased ERK activity at
both 1 and 4 minutes after CSF-1 addition. The rightmost panel is a
longer exposure to compare basal ERK activity with that in the presence
of forskolin/IBMX only. The magnitude of the increase induced by
forskolin/IBMX varies between experiments (see Fig 3). (B)
Immunoprecipitated ERK2 was analyzed for tyrosine phosphorylation by
Western blotting with an antiphosphotyrosine antibody (top). The blot
was then stripped and reprobed with anti-ERK2 monoclonal antibody
(bottom). (C) Cells were pretreated with varying doses of forskolin or
IBMX as indicated, followed by CSF-1 stimulation. ERK immune complex
kinase assays were performed as described above. (D) Cells were
stimulated with CSF-1 alone ( ), pretreated with forskolin/IBMX for
20 minutes and then stimulated with CSF-1 ( ), or treated with CSF-1
and forskolin/IBMX simultaneously ( ). Aliquots were taken at the
indicated time points, and lysates were prepared and assayed for ERK2
activity. (E) MEK1 was immunoprecipitated and activity measured with
recombinant KD MAPK protein as substrate (left panel). MEK1 or MEK2 was
immunoprecipitated from the same preparation of lysates and assayed for
kinase activity (right panel). Parallel MEK1 and MEK2 immune complex
kinase assays were repeated twice with similar results.
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To examine the effect of cAMP, PKA was activated with either btcAMP or
forskolin in combination with IBMX, a cyclic nucleotide phosphodiesterase inhibitor. Cells were pretreated with PKA-activating agents for 10 or 30 minutes before CSF-1 stimulation. In the absence of
CSF-1, cAMP had a modest effect on ERK activity, increasing it by
4.6-fold above basal in the experiment shown (Fig 2A, right panel),
although the magnitude of increase varies between experiments. On
average, forskolin/IBMX alone increased ERK activity by 2.6- ± 0.5-fold (n = 10, P < .01 using the Student's two-sided
t-test; Fig 3). In the presence of
CSF-1, cAMP markedly enhanced ERK activation by an additional 5.6- ± 0.5-fold (n = 11, P < .001) and 4.6- ± 1.1-fold (n = 4, P < .05) for forskolin/IBMX and btcAMP, respectively (Figs 2A and 3). To eliminate the possibility that the increased MBP
phosphotransferase activity present in ERK immunoprecipitates was a
result of coprecipitating PKA, all ERK assays included PKI, a PKA
inhibitor. ERK activation requires the phosphorylation of a threonine
and tyrosine. ERK immunoprecipitates were blotted with an
antiphosphotyrosine antibody, and the results (Fig 2B, top panel)
confirm that the increase in ERK kinase activity in the presence of
cAMP and CSF-1 was accompanied by enhanced ERK tyrosine
phosphorylation. Gel mobility shifts of ERK have frequently been used
as evidence for kinase activation. In agreement, Fig 2B (bottom panel)
shows an increase in the amount of a slower migrating species when ERK
immunoprecipitates were probed with a monoclonal ERK antibody. We also
determined the dose-dependence of ERK activity on forskolin and found
that the magnitude of synergistic activation reached a maximum with 10 µmol/L forskolin and remained constant between 10 and 50 µmol/L
forskolin (Fig 2C). A dose of 50 µmol/L forskolin with 0.5 mmol/L
IBMX was used in all subsequent experiments, unless otherwise stated.
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| Fig 3.
Plot summarizing data from multiple experiments. ERK2 and
MEK1 activities were measured as described in Fig 2 and the fold
activation was calculated by normalizing to activities measured in
untreated controls ( CSF-1) or to activities in samples treated with
CSF-1 only (+ CSF-1) using the formula 1+ ([with cAMP] [no
cAMP])/([no cAMP] [untreated]). Data shown represent the means ± SE, with the number of experiments (n) indicated. Statistically
significant differences between untreated and cAMP-treated pairs are
denoted by asterisks: *P < .05; **P < .001.
|
|
cAMP is growth-inhibitory for CCL39 fibroblasts, and this was reported
to correlate with inhibition of mitogen-stimulated ERK activation when
measured at a fixed time point. However, it was subsequently
demonstrated that cAMP pretreatment delayed ERK activation by 5 to 10 minutes, but did not affect the magnitude of the
response.44 To determine if the observed synergism between cAMP and CSF-1 reflects a shift in activation kinetics rather than true
synergism, we compared the time course of ERK activation in response to
(1) CSF-1 addition alone, (2) a 20-minute pretreatment with
forskolin/IBMX followed by CSF-1, and (3) the addition of CSF-1 and
forskolin/IBMX simultaneously. Figure 2D shows that CSF-1-stimulated
ERK activity was transient and was back to unstimulated levels after 15 minutes. Both cAMP treatment regimens resulted in a synergistic
activation of ERK: at 4 minutes after stimulation, ERK activity was
increased by approximately 70-fold if cells were pretreated and by
approximately 45-fold if CSF-1 and forskolin/IBMX were added together.
At the subsequent time points, ERK activity was elevated to a similar
degree for both cAMP treatment regimens: 40-fold above basal at 15 minutes and 10-fold above basal at 30 minutes. We also determined the
time course of PKA activation (assayed by Kemptide phosphorylation,
data not shown) and found that the extent of synergistic ERK activation
in response to cAMP and CSF-1 costimulation tracked closely the
magnitude of PKA activation. These data demonstrate that maximal
cooperation between CSF-1 and cAMP occurs when there is maximal overlap
in the intensity of the individual signals. A 20-minute pretreament
period with cAMP-elevating agents was adopted in all subsequent
experiments.
CSF-1 activates MEK1 and not MEK2 and neither is affected by cAMP
treatment.
MEKs are the predominant ERK kinases in mammalian cells. To determine
if the enhanced ERK stimulation can be explained by corresponding
changes in MEK activity, MEK1 was immunoprecipitated and its activity
measured against a recombinant KD MAPK as substrate. Despite the much
increased ERK activity in the presence of cAMP and CSF-1 compared with
CSF-1 alone, cAMP elevation was found to have a minimal effect on
CSF-1-induced MEK activity (Fig 2E). Because small changes in MEK
activity may not be detected by phosphorylation of KD-MAPK, a coupled
MEK assay was performed in which immunoprecipitated MEK1 was allowed to
phosphorylate recombinant wild-type MAPK and activation of MAPK was
determined by MBP phosphorylation. Even this more sensitive assay did
not detect a significant increase in MEK1 activity in the presence of
cAMP elevation (data not shown). We also determined ERK2 and MEK1
activities in the absence and presence of forskolin/IBMX pretreatment
at different CSF-1 concentrations (0, 0.01, 0.1, and 1 nmol/L) and at
different times after CSF-1 addition (0, 1, 4, 10, 15, and 30 minutes).
A similar dissociation between ERK2 and MEK1 activities was observed in
response to cAMP stimulation under all conditions tested (data not
shown). In addition to MEK1, MEK2 is also known to activate ERK1/2. To
determine if MEK2 may be mediating the increase in ERK activation,
lysates from 32D/CSF-1R cells treated with CSF-1 for various times were immunoprecipitated with a MEK2 antibody in common usage45
and assayed for activity against KD-MAPK (Fig 2E). Maximal MEK2
activity was estimated to be less than 1% that of MEK1 measured
simultaneously. Effective immunoprecipitation of MEK2 was verified by
blotting the immunoprecipitates with MEK2 antibodies (not shown). Thus, MEK2 did not contribute significantly towards ERK activation by CSF-1
in the absence (Fig 2E) or presence (not shown) of cAMP treatment.
Figure 3 summarizes the results from multiple experiments, illustrating
the synergistic activation of ERK but not of MEK1 by cAMP and CSF-1.
cAMP cooperates with IL-3 to synergistically activate ERK in 32D and
FDC-P1 cells.
We next determined if the observed cooperative activation of ERK
between cAMP and CSF-1 is unique to CSF-1 or if cAMP has a similar
effect on ERK stimulation by other mitogens in these cells. 32D cells
are IL-3-dependent for proliferation and survival. Figure 4A shows that IL-3-activated ERK2
and pretreatment with forskolin/IBMX further increased ERK activation
by more than eightfold. As with CSF-1, the increase in ERK activity in
the presence of cAMP was not reflected by detectable increases in MEK1
activity (the small increase in MEK1 activity depicted in Fig 4A was
not consistently observed between experiments). MEK2 was also not activated in response to IL3 (data not shown). IL-3 and cAMP effects were further investigated in a second IL-3-dependent, nonleukemic, myeloid progenitor cell line, FDC-P1, and synergistic activation was
also observed (Fig 4A). These data demonstrate that cAMP cooperates with two different classes of growth factor receptors, a tyrosine kinase receptor (CSF-1R) and a cytokine receptor (IL-3R), to activate the ERK pathway in murine myeloid progenitors.
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| Fig 4.
cAMP synergizes with IL-3 to activate ERK2 in 32D/CSF-1R
and FDC-P1 cells. Cells were treated as described in the legend to Fig
2, except that they were stimulated with murine rIL-3. (A) Cells were
pretreated or not with forskolin/IBMX and stimulated with IL-3 for 15 minutes. ERK (top) and MEK1 (bottom) assays were performed as described
in Fig 2. (B) Time dependence of ERK2 stimulation by CSF-1 (top panel)
or IL-3 (bottom panel) in the presence () or absence () of
forskolin (10 µmol/L) and IBMX (0.1 mmol/L) pretreatment. Cells were
starved in medium containing 10% FBS but no IL-3 for 18 hours and
CSF-1 or IL-3 was added. Aliquots were taken at the indicated time
points (0, 5 minutes, 30 minutes, 1 hour, 3 hours, 5 hours, 7 hours, 9 hours, 12 hours, and 22 hours) and processed for ERK activity. The
experiments shown in (A) and (B) have been repeated twice with very
similar results.
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|
ERK stimulation by IL-3 in the presence or absence of forskolin/IBMX
was compared with that observed for CSF-1 and monitored over a 22-hour
time period (Fig 4B). Because 32D/CSF-1R cells cannot survive for
prolonged periods with CSF-1 as the sole growth factor without serum
(A.W.L., unpublished observations), they were starved for
24 hours in medium containing 10% FBS but no IL-3 or CSF-1. This
resulted in a higher basal level of ERK activity and a somewhat lower
fold induction compared with that seen with serum-free medium. In the
absence of forskolin/IBMX, the peak of IL-3-stimulated ERK activity
was slightly delayed (maximum at 15 minutes) compared with that induced
by CSF-1 (maximum at 5 minutes). cAMP did not alter the kinetics of ERK
activation during the 22 hours of monitoring; rather, the primary
effect was on the magnitude of the response, as was seen with cells
starved in serum-free medium (Fig 2D). Because the kinetics of
cAMP-mediated activation was very similar for both CSF-1 and IL-3,
pathways common to both growth factors are likely to being modulated by cAMP.
Upregulation of ERK activity by cAMP and CSF-1 is reflected in a
synergistic increase in p90rsk activity.
We sought to determine if the synergism between cAMP and CSF-1 was
transmitted downstream of ERK. MEK1-ERK is both necessary and
sufficient for activation of all three isoforms of the ribosomal S6
kinase, p90rsk46; furthermore, there is evidence supporting
a direct role for ERK in phosphorylating and activating
p90rsk.46 Cell lysates were immunoprecipitated
with an anti-RSK1 antibody and kinase activity towards S6 peptide was
determined (Fig 5). CSF-1 stimulated a
20-fold increase in RSK1 activity that was further increased by almost
twofold in the presence of forskolin/IBMX. Because the targets for
p90rsk are transcriptional factors, these data suggest that
the synergistic activation of ERK by cAMP and CSF-1 is likely to have a
physiological role.
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| Fig 5.
cAMP upregulates CSF-1-stimulated p90rsk
activity. 32D/CSF-1R cells were treated as described in the legend to
Fig 2. Lysates were immunoprecipitated with anti-p90rsk and
the immunoprecipitates were assayed for kinase activity towards S6
peptide. Data represent the means ± SE from two independent
experiments.
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|
Oncogenic Ras cooperates with cAMP to activate ERK in a
Raf-1-independent and MEK1-dependent manner.
The next series of experiments were designed to determine the steps in
the CSF-1-induced ERK activation cascade necessary for mediating
cAMP's synergistic effects. ERK can be activated by both Ras-dependent
and independent pathways. To determine if Ras is involved in the
synergistic activation of ERK by cAMP in 32D/CSF-1R cells, oncogenic
Ras (61L) or its empty vector control was cotransfected with a
hemagglutinin (HA)-tagged ERK2 (HA-ERK2). HA-ERK2 serves as a reporter
to monitor 61LRas's effect on ERK activity in transfected cells. Cells
were processed 24 hours after transfection. In this and subsequent
experiments using HA-ERK2, Western blotting with anti-HA antibody was
first performed to assess expression levels for the different
transfections. Lysates containing equivalent amounts of HA-ERK2 were
then used in immune complex kinase assays. Results of a representative
experiment are shown in Fig
6A. Based on five independent transfections, it was observed that the
steady-state expression of 61LRas resulted in a 10.1- ± 2.6-fold
increase in basal HA-ERK2 activity compared with vector control. HA-ERK
activity was not further increased by CSF-1, which suggests that, under
normal conditions, Ras-GTP may be limiting for CSF-1-mediated ERK
activation. In contrast to the lack of an effect by CSF-1,
forskolin/IBMX treatment synergized strongly with 61LRas to further
activate ERK. The average induction by forskolin/IBMX from four
separate experiments was 4.7- ± 1.8-fold (P < .04) over
that obtained in its absence, similar in magnitude to that observed for
the cooperation between CSF-1 and cAMP (Fig 3). To determine if the
activation of HA-ERK2 by cAMP and 61LRas was MEK1-dependent, we made
use of a dn-MEK1 expression construct, in which the serines required
for its activation (S218, S222) have been replaced by alanines. Figure
6B shows that dn-MEK1 inhibited 61LRas-stimulated HA-ERK2 activity by
70% to 80% and eliminated most of the increase in activity induced by
cAMP. To investigate if Raf-1 is involved in the cooperation between
61LRas and cAMP, 32D/CSF-1R cells were transfected with fourfold more
61LRas DNA (20 µg) than normally used in cotransfection experiments,
because an epitope-tagged Raf-1 construct was not available. FACS
analysis showed that a quantitative shift in mean Ras fluorescence was achieved for the transfectants (Fig 6C), indicating that the majority of the cells expressed similar levels of 61LRas. It was found that
61LRas expression increased basal Raf-1 activity by 2.7-fold compared
with vector control (not shown), and this activity was significantly
inhibited by cAMP (Fig 6C). Thus, the data indicate that cAMP can
synergize with oncogenic Ras to markedly increase ERK activity via an
MEK1-dependent mechanism but that Raf-1 did not appear to be involved.
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| Fig 6.
cAMP synergizes with oncogenic Ras to stimulate
ERK in an MEK1-dependent manner. 32D/CSF-1R cells were cotransfected
with vector (7 µg) and HA-ERK2 (2 µg) or with 61LRas (6 µg),
HA-ERK2 (1 µg), and vector (2 µg). Twenty-four hours later,
surviving cells were starved and pretreated or not with forskolin/IBMX
before stimulation with CSF-1 for 4 minutes. (A) Transfected ERK2 from
lysates normalized to contain equivalent levels of HA-ERK2 was
immunoprecipitated with anti-HA antibody and kinase activity towards
MBP was determined (top). Anti-HA Western blot of transfected HA-ERK2
is shown (bottom). The results are representative of four independent
sets of transfections. (B) Cells were cotransfected with 61LRas (3 µg), HA-ERK2 (1 µg), and the indicated amounts of dn-MEK1, with the
total DNA content kept constant with empty vector. HA-ERK2 kinase
activity (top) and Western blot (bottom) are shown. (C) FACS analysis
shows Ras expression level in cells 24 hours after transfection with
either vector (20 µg) or 6LRas (20 µg). Cells were permeabilized
and stained with anti-Ras antibody (Y13-258). As a negative control,
Ras-transfected cells were stained with an irrelevant primary antibody
(anti-CD4). Abscissa: log relative fluorescence intensity; ordinate:
relative cell number. Raf-1 kinase activity in cells transfected with
61LRas, in the absence or presence of cAMP-elevating agents, is shown
on the right.
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|
To determine if HA-ERK2 might be activated by autocrine factors
secreted by cells expressing oncogenic Ras, a mixing experiment was
performed. Two pools of cells, transfected independently with 61LRas or
HA-ERK2, were washed 2 hours after transfection and cocultured in fresh
media for the remainder of the experiment. Under these conditions,
HA-ERK2 activity of HA-ERK-transfected cells mixed with cells
transfected with 61LRas was 3.2-fold higher than when mixed with cells
transfected with the vector-control, compared with a 8.2-fold increase
in cells cotransfected with 61LRas and HA-ERK2. This indicates that
there was some secretion of autocrine factors but that 61LRas also
directly activated HA-ERK2.
None of the Raf isoforms is responsible for cAMP-dependent ERK
superactivation.
Because Raf-1 did not appear to be activated in the presence of cAMP,
we sought to determine if MEK was activated by other Raf family
members. Expression of the three Raf members in 32D/CSF-1R cells was
determined by Western blotting (Fig 7A).
Raf-1 and A-Raf were easily detected. Multiple bands (90 to 95 kD and
65 to 70 kD) were observed on the B-Raf blot but appeared to be
specific as they were competed off by a blocking peptide. Also, B-Raf
is present at significantly lower levels in 32D cells, in comparison to
PC12, a cell line in which cAMP activates MEK/ERK by the Ras/B-Raf route.27 We next determined the activity of the three Rafs
in response to CSF-1 ± cAMP by means of immune complex kinase
assays using as substrate recombinant KD MEK1. CSF-1 stimulated a
twofold to threefold increase in Raf-1 activity that was completely
inhibited by pretreatment with forskolin/IBMX or btcAMP (Fig 7B),
similar to what was observed for 61LRas (Fig 6C). Although B-Raf was
present at low levels, it exhibited very high basal kinase activity;
however, no increase in B-Raf activity could be detected in response to CSF-1 or IL-3, alone or in combination with cAMP-elevating agents (Fig
7B). The kinase activity detected was confirmed to be due to B-Raf,
because preincubation of the B-Raf antibody with its blocking peptide
completely prevented the phosphorylation of KD-MEK by B-Raf
immunoprecipitates (data not shown). Also, A-Raf kinase activity
towards KD-MEK could not be detected, basally or in response to
treatments, despite abundant amounts of A-Raf protein in the immunoprecipitates (data not shown). These results indicate that Raf-1
but not A-Raf or B-Raf was activated by CSF-1 and IL-3 (not shown) in
32D/CSF-1R cells and none of the Raf isoforms appeared to be
responsible for ERK activation in the presence of cAMP and CSF-1.
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| Fig 7.
CSF-1 activates Raf-1 but not B-Raf or A-Raf and none is
activated in the presence of cAMP and CSF-1. (A) Western blot analysis
of the three Raf isoforms in 32D/CSF-1R cells. Where indicated,
blocking peptide (1 and 3 µg/mL) was preincubated with the
appropriate antibody. The middle panel is a longer exposure of the
B-Raf segment of the blot shown on the left. Equal amounts of lysates
(50 µg) from 32D/CSF-1R and PC12 cells were also Western blotted for
B-Raf, showing significantly higher levels of expression in PC12 cells
(right panel). "+" refers to a parallel blot that was incubated
with anti-B-Raf and its blocking peptide (1 µg/mL). (B) 32D/CSF-1R
cells were treated as described in Fig 2 and Raf-1 or B-Raf was
immunoprecipitated. Kinase activity was measured using a recombinant
KD-MEK1 as substrate. Shown is a plot summarizing data (means ± SE)
from multiple (n) experiments. Only CSF-1-stimulated Raf-1 activity is
significant (*) compared with basal (P < .05).
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|
The role of MEK1 in mediating ERK2 activation by CSF-1 and cAMP.
Figures 2 and 3 show that CSF-1 and cAMP activated ERK
disproportionately compared with MEK1, but Fig 6 indicates that MEK1 lies on the major pathway leading to synergistic ERK activation by cAMP
and oncogenic Ras. We therefore examined the role of MEK1 in
CSF-1-stimulated ERK activation. Cells were cotransfected with HA-ERK
and dn-MEK1 or a vector control. Western blotting with a MEK1 antibody
indicated that, 24 hours after transfection, overall MEK1 levels were
increased by 10-fold in cells transfected with dn-MEK1 compared with
vector-transfected cells (Fig 8A, top). The
results from four independent transfections are shown in Fig 8A
(bottom). It is seen that dn-MEK1 significantly blocked activation of
HA-ERK in cells stimulated with CSF-1 alone or in combination with
cAMP. A concern with dn-MEK1 is that it may be exerting its inhibitory
function by binding to an upstream activator shared by MEK and another
MAPKK, resulting in the unknown MAPKK rather than MEK being uncoupled
from the activation signal. To further confirm the critical role of
MEK, we used the well-characterized and widely used synthetic
inhibitor, PD98059, reported to be specific for MEK1/2.47
PD98059 was added to the culture medium 1 hour and 40 minutes before
the addition of forskolin/IBMX, which was followed 20 minutes later by
CSF-1 (or IL-3) stimulation for 4 (or 10) minutes. ERK activities were
measured and shown in Fig 8B. They demonstrate that 100 µmol/L
PD98059 inhibited the majority of the ERK activity in response to
ligand alone or in combination with forskolin/IBMX. A similar extent of
ERK inhibition was also obtained with 50 µmol/L of PD98059. Taken
together, our results suggest that the synergistic activation of ERK by
CSF-1 (or IL-3) and cAMP depends on MEK1 activation.
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| Fig 8.
MEK activity is required for the synergistic activation
of ERK by CSF-1 and cAMP. (A) 32D/CSF-1R cells were cotransfected with
HA-ERK2 (2 µg) and either vector (10 µg) or dn-MEK1 (10 µg).
Cells were processed 24 hours later as described in Fig 5. Western blot
of total MEK1 (endogenous plus transfected) is shown in the top panel.
MBP kinase activity in HA-ERK2 immunoprecipitates was determined and
the results from four independent cotransfections with HA-ERK2 and
dn-MEK1 or vector control are shown in the bottom panel (means ± SE).
To emphasize the effect of dn-MEK1, HA-ERK activities measured in the
presence of dn-MEK1 are normalized to those from vector-control cells
for each condition. (B) 32D/CSF-1R cells were starved and treated
with 100 µmol/L PD98059 for 1 hour and 40 minutes before the addition
of forskolin/IBMX. This was followed 20 minutes later by CSF-1 or IL-3.
Endogenous ERK2 was immunoprecipitated and MBP kinase activity
determined. The experiment has been repeated with 50 µmol/L PD98059
with very similar results.
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ERK activation opposes cAMP's growth inhibitory and
apoptosis-promoting effects.
Because cAMP is growth-inhibitory (Fig 1) yet synergizes with growth
factors to activate the ERK pathway (Fig 3), we wish to assess whether
the synergistic activation of ERK plays a role, if at all, in cellular
proliferation. To do this, we made use of PD98059, which was
demonstrated in Fig 8 to abolish most of ERK activation in response to
cAMP and CSF-1 or IL-3. No direct toxic effects have been reported for
PD98059. Exponentially growing cells were thoroughly washed before
seeding into fresh media containing 10% FBS. They were treated with 50 µmol/L PD98059 for 2 hours before the addition of btcAMP, and this
was followed 20 minutes later by CSF-1 or IL-3. Cells were counted
daily and representative results are shown in
Fig 9A. Based on three independent
experiments, PD98059 was found to reduce both CSF-1- and
IL-3-dependent growth by 60% to 70% (P < .02) after 3 days
of culture, indicating that ERK activity is required for optimal
growth. btcAMP addition to CSF-1-stimulated cells caused growth
cessation and cell death, and this was markedly enhanced by the
inclusion of PD98059. IL-3-treated cells still proliferated in the
presence of btcAMP, although cell numbers after 4 days of culture were
only 30% of those growing without btcAMP. The addition of PD98059 to
cells cultured with IL-3 and btcAMP had a dramatic,
greater-than-additive effect, as evidenced by rapid cell death (Fig
9A). PD98059 similarly affected cells treated with forskolin in the
presence of CSF-1 or IL-3 (data not shown). The ability of IL-3 to
support proliferation in the presence of cAMP, albeit at a
significantly reduced level, indicates that IL-3 may activate pathways
important for proliferation that are not inhibited by cAMP, or that the
strength of the IL-3 signal exceeds the threshold necessary for cell
cycle progression. In both CSF-1- and IL-3-stimulated growth, ERK
activity is necessary for maintaining the residual proliferation
observed in the presence of cAMP, because inhibition of the MEK-ERK
pathway resulted in growth arrest and eventual cell death.
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| Fig 9.
ERK activation by CSF-1 and cAMP opposes cAMP's
growth-inhibitory and apoptosis-promoting effects. (A) Exponentially
growing 32D/CSF-1R cells were thoroughly washed and then seeded into
medium without CSF-1 or IL-3 in the presence or absence of 50 µmol/L
PD98059 (PD) and allowed to incubate for 1 hour and 40 minutes. btcAMP
(1 mmol/L) was added, followed by 5 nmol/L CSF-1 (left) or 100 U/mL of
rIL-3 (right) 20 minutes later. DMSO was present in the same amounts in
all samples. Cell counts were performed in duplicate daily. Duplicate
cell counts showed less than a 5% error in most cases. (B) Cells were
treated as described in (A) using either 1 mmol/L btcAMP or 30 µmol/L
forskolin. Cytoplasmic DNA was isolated from a fixed number of starting
cells as described in Materials and Methods and analyzed by agarose gel
electrophoresis and ethidium bromide staining after 3 days (left) or 24 hours (right). Relative numbers of viable cells remaining after 24 hours under the different conditions for the experiment on the right
are as follows: CSF-1 (100%), CSF-1+PD (67%), CSF-1+btcAMP
(46%), CSF-1+btcAMP+PD (35%), CSF-1+forskolin (67%), and
CSF-1+forskolin+PD (43%).
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The role of ERK in mediating survival was next assessed by DNA
fragmentation analysis. Exponentially growing cells (1.6 × 106) were thoroughly rinsed and seeded into
media containing CSF-1 and various combinations of PD98059 and
forskolin or btcAMP as described above. Cells were harvested 24 hours
later and low molecular weight, soluble DNA was extracted and analyzed
for DNA laddering as described in Materials and Methods. The results
demonstrate that DNA laddering was already evident in cells that have
been growing in the presence of PD98059 for 1 day (Fig 9B, right
panel), suggesting that ERK activity is required for optimal protection against apoptosis by CSF-1. By 3 days, the intensity of laddering was
comparable to that observed in cells that have been completely deprived
of CSF-1 and IL-3 for the same period (Fig 9B, left panel). Furthermore, PD98059 markedly enhanced the amount of apoptosis observed
in cells treated with either btcAMP or forskolin, showing that the
synergistic activation of ERK protects cells from cAMP-induced apoptotic effects. Thus, it appears that CSF-1 and cAMP activated a
growth- and survival-promoting signal mediated by ERK and that cAMP
also activated other opposing, growth-inhibitory, and
apoptosis-promoting signals in myeloid progenitors.
| |
DISCUSSION |
ERK/MAPK and cAMP are ubiquitous and critical cellular signaling
components. A wide range of cell-type-dependent and
receptor-type-dependent interactions between them have been
observed.21-27 The present study focuses on the effect of
cross-talk between cAMP and growth factors on the ERK pathway in
myeloid progenitors. The key findings are as follows. (1) cAMP
synergized with CSF-1 or IL-3 to markedly upregulate ERK activity. This
synergism was transmitted downstream to at least one ERK substrate,
p90rsk. (2) The cooperative activation of ERK by cAMP and
growth factors was recapitulated by cAMP treatment of 32D cells
transfected with oncogenic Ras. (3) The synergistic activation of ERK
by cAMP and CSF-1 or IL-3 did not involve any of the Raf isoforms. (4)
Both expression of dn-MEK1 and treatment with PD98059 prevented the observed synergistic activation, indicating that MEK1 activity was
required for the cooperation between cAMP and growth factors; however,
there is a dissociation between the levels of MEK1 and ERK2 activities,
suggesting that cAMP also targets other factors that modulate ERK
activity. (5) Finally, an intact ERK response was required for optimal
CSF-1- and IL-3-dependent cell proliferation and survival, and its
inhibition markedly accelerated the growth inhibition and apoptosis
induced by cAMP. This is the first report describing cooperation in
myeloid progenitors between cAMP and growth factors such as CSF-1 and
IL-3 to activate the ERK pathway. This cooperation occurs at the level
of ERK and is Ras- and MEK-dependent but independent of the Rafs. The
upregulated ERK activity is important for protecting hematopoietic
cells from the antiproliferative and proapoptotic effects of cAMP. A
schematic summarizing our findings is shown in
Fig 10.
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| Fig 10.
Schematic illustrating how growth factors such as CSF-1
and IL-3 may cooperate with cAMP/PKA to activate the
ERK/p90rsk pathway in myeloid progenitors. CSF-1 stimulates
the activities of both Raf-1 and ERK in 32D cells. In the presence of
cAMP, Raf-1 activation is prevented yet ERK activity is enhanced. The
simplest explanation is that CSF-1 uses an alternate (not Raf-1)
cAMP-insensitive kinase as the MAPKKK. Activation of MAPKKK is likely
to be Ras-dependent, because expression of oncogenic Ras together with
elevations in cAMP levels can recapitulate the synergistic stimulation
of ERK by CSF-1 and cAMP. Whether cAMP can itself activate MAPKKK is
not clear (see text). Instead, the dominant stimulatory effect of cAMP
appears to be at a step after MEK1 activation, because MEK1 activity
itself is not enhanced in the presence of cAMP but is required for the
synergistic action of cAMP. Inhibition of the MEK-ERK pathway results
in a significant but incomplete suppression of cell proliferation,
indicating that growth factors such as CSF-1 and IL-3 activate other
pathways required for optimal proliferation and survival in myeloid
progenitor cell lines. These pathways could be mediated by both
Ras-independent (depicted by pathways emanating from the receptor) and
-dependent (depicted by pathways emanating from Ras) mechanisms and
both are potentially targets for cAMP action. cAMP and PKA can also
presumably influence pathways in the cell not directly activated by
CSF-1 or IL-3 (depicted by an arrow emanating from PKA not targeted at
a receptor-activated pathway).
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|
Our observation of a cooperative activation of the ERK pathway by cAMP
and growth factors is not an artifact of the engineered cell line used,
because very similar effects were found for both CSF-1 and IL-3, with
the latter acting on endogenous IL-3 receptors. IL-3 also cooperated
with cAMP to activate ERK in a second myeloid progenitor cell line,
FDC-P1. The receptors for CSF-1 and IL-3 are different: CSF-1R is a
receptor tyrosine kinase, whereas IL-3R is a heterodimeric cytokine
receptor that is not a tyrosine kinase but is phosphorylated by the
cytoplasmic JAK family of tyrosine kinases. Coupling to the Ras/MAPK
pathway by both receptor systems is thought to proceed through similar
links, namely SHC tyrosine phosphorylation and association with
Grb2/Sos.48 Therefore, it is not surprising to find that
cAMP modulated CSF-1 and IL-3 stimulation of the ERK pathway in similar
ways.
The synergistic activation of ERK induced by costimulation with cAMP
and growth factors was recapitulated by cAMP treatment of cells
expressing oncogenic Ras. This suggests that cross-talk between cAMP
and CSF-1 or IL-3 is likely to be occurring at the level of Ras or
downstream of Ras in the Ras/MAPK pathway. In data not shown, PKA
activation had no effect on CSF-1-stimulated elements upstream of Ras,
including receptor tyrosine phosphorylation, SHC tyrosine
phosphorylation, and SHC/Grb2 association. Raf-1 was activated in
response to CSF-1 in the absence but not in the presence of
cAMP-elevating agents, in agreement with the well-documented inhibition
of Raf-1 by PKA.20 Because inhibition of Raf-1 by cAMP is
associated with an increase in ERK activity stimulated by CSF-1 and
IL-3, the simplest explanation is that there is an MAPKKK in myeloid
progenitors whose activity is not inhibited by cAMP. Other reports have
also described the possible existence of Raf-1-independent mechanisms
for activating ERK in hematopoietic cells: in macrophages,
dominant-negative Ras expression inhibited CSF-1-stimulated MEK and
ERK activities but had no effect on Raf-1 activation,49 and
in a myeloid leukemic cell line, G-CSF-stimulated ERK activation is
not inhibited by cAMP.50 However, ERK insensitivity to cAMP
is not universal in hematopoietic cells, because cAMP inhibited ERK
activation by GM-CSF and steel factor in a megakaryocytic leukemic cell
line.51 One question is whether the MAPKKK implicated by
our findings is also stimulated by cAMP. Figure 3 shows that, on
average, forskolin/IBMX increases basal ERK activity by 2.6-fold. Because it is possible that the increase in ERK activity is due to
cooperation of cAMP with residual activated Ras not eliminated by our
starvation conditions, we cannot conclude, at this time, that cAMP can
stimulate MAPKKK activity.
What is the possible identity of the cAMP-insensitive MAPKKK?
In some PC12 sublines, cAMP activates the small G protein Rap1, which
in turn activates the 95-kD form of B-Raf to stimulate
ERK.27 32D cells express several forms of B-Raf, including
a 90- to 95-kD species, but the overall expression level is low
compared with PC12 cells (Fig 7A). This may account for our inability
to detect B-Raf activation in response to cAMP. In addition to the
Rafs, other molecules have been described as MAPKKKs. MEKK1 and MEKK3 apparently can activate MEK-ERK in transient overexpression
studies.52 MEKK1 is expressed in 32D cells as determined by
Western blotting, but we did not find evidence for its activation by
CSF-1 (A.W.L., unpublished observations); the expression
pattern of MEKK3 in myeloid cells is not known. Work is in progress to
assess candidate signaling molecules capable of mediating the
cooperative activation of ERK by cAMP and CSF-1.
The experiments with PD98059 and dn-MEK1 (Fig 8) provide strong
evidence for a MEK1 requirement in the synergistic activation of ERK by
cAMP and CSF-1. Yet there is not a corresponding synergistic activation
of MEK1 (Fig 3), suggesting that cAMP is modulating other factors that
affect either the ability of ERK to be activated by MEK1 or the
inactivation of ERK subsequent to its activation by MEK1. A similar
dissociation between MEK and ERK activation has been reported by
Samuels et al53; in contrast to the findings of the present
study, these investigators reported activation of MEK but not ERK in
Rat1 fibroblasts upon Raf-1 stimulation. The dissociation was
attributed to phosphatases acting on ERK. In support of the possibility
that ERK activity in 32D cells is regulated by phosphatases and that
cAMP may act through phosphatases to influence ERK activation, we have
observed that inhibition of serine/threonine phosphatases such as PP2A
by okadaic acid resulted in a marked (11.4-fold) increase in ERK
activity in response to CSF-1 over that observed in the presence of
CSF-1 alone. In comparison, MEK1 activity was only increased by 68%
under the same conditions. Another possible mechanism is for cAMP to be affecting the mutual accessibility of MEK and ERK. In yeast, Ste5 serves as a scaffolding protein that holds Ste11 (MAPKKK), Ste7 (MAPKK), and Fus3/Kss1 (MAPK) together in a productive kinase cascade.54 An Ste5 analog has not been definitively
identified in mammalian cells, but an attractive model would be for
cAMP to modify this scaffolding protein in a way to enhance the ability of ERK to be phosphorylated by MEK. Further work will be needed to
distinguish between these possibilities.
To the best of our knowledge, this study also shows for the first time
a role for ERK activation in CSF-1-mediated survival and proliferation
of myeloid cells. We have obtained similar findings for IL-3 that are
generally in agreement with those of Perkins et al,55 who
expressed a dn-MEK1 in BAF3 cells to examine ERK function in
IL-3-mediated proliferation. These investigators reported that
inhibition of ERK activation increased the IL-3 concentration necessary
for optimal DNA synthesis and survival, although the effect was
abrogated at high concentrations of IL-3. In contrast, we saw a
significant reduction (by 60% to 70%) in cell numbers in the presence
of PD98059 at saturating amounts of IL-3. A possible explanation is
that dn-MEK1 is not as effective as PD98059 in inhibiting ERK
activation. The decrease in CSF-1-dependent cell growth when ERK
activity was inhibited could be a consequence not only of reduced cell
cycle transit, but also of decreased survival as well, because 32D
cells apoptose to some extent in the presence of PD98059. Because
blocking the ERK pathway by PD98059 did not completely eliminate
proliferation, other CSF-1- and IL-3-stimulated pathways must also
contribute (Fig 10).
cAMP elevation had a net growth-inhibitory effect (Fig 1), so it was
unexpected to find that CSF-1- and IL-3-induced ERK2 activity was
increased by fivefold and ninefold, respectively, by costimulation with
cAMP. These results suggest that cAMP is exerting inhibitory influences
that ERK activation cannot override or the supranormal levels of ERK
activity may itself be instrumental in mediating growth suppression.
The latter possibility has been invoked to explain the correlation
observed between IgM cross-linking-induced ERK activation and
apoptosis in B cells.56 To distinguish between these
possibilities, we used PD98059 to inhibit ERK activation. We found that
synergistic activation of ERK by cAMP and CSF-1 or IL-3 contributed
towards protection of cells from cAMP-induced apoptosis and growth
inhibition. Thus, in myeloid progenitor cell lines such as 32D and
FDC-P1, it appears that growth factors can use the ERK pathway to
counter inhibitory effects produced by increases in intracellular cAMP.
How might increased ERK activity modulate cAMP's inhibitory actions?
Cyclin D1 induction has been linked to ERK activation in a number of
studies57,58 and may be a target for cAMP's inhibitory
action.59 One can speculate that a consequence of the
synergistic activation of ERK by cAMP and growth factors is to increase
G1 cyclin levels to partially overcome the negative effects
of cAMP. cAMP also has targets not involving the ERK pathway: cAMP was
found to increase the levels of the cell cycle inhibitor,
p27kip1, in macrophages60 and to antagonize
growth factor-dependent activation of p70s6k, the major S6
kinase in mammalian cells whose activation depends on
phosphatidylinositol 3-kinase.61 We have previously
demonstrated that CSF-1 activates phosphtaidylinositol 3-kinase in
32D/CSF-1R cells29 and is likely to represent one of the
pathways required for optimal proliferation and survival (Fig 10).
Lastly, it should be noted that Raf-1 can have functions independent of
its role in the ERK pathway. In v-abl-transformed fibroblasts,
inhibition of Raf-1 by cAMP did not inhibit ERK activation but instead
eliminated override mechanisms that would otherwise have suppressed
c-myc-induced apoptosis.62
The findings presented here lead to a number of additional questions.
In addition to CSF-1R and IL-3R, do other growth factor receptors
expressed on myeloid progenitors, eg, c-kit, GM-CSF receptor,
and IL-6 receptor, also cooperate with cAMP to stimulate ERK and oppose
cAMP's growth-suppressive effects? If the interactions with cAMP
differ between different myeloid growth factors as a consequence, for
example, of growth factors coupling to different MAPKKKs, then
expansion or depletion of subsets of myeloid progenitors could be
achieved through the amount of cAMP produced and its selective
interactions with the repertoire of growth factors and their receptors
expressed on the cell surface. Differentiation along hematopoietic
lineages may be influenced by intracellular cAMP levels and PKA
activation as well: during the differentiation of monocytes to
macrophages, both adenylate cyclase-specific activity and PKA protein
levels were reported to increase dramatically.63 The impact
on the ERK/MAPK pathway is not known. Elucidating the complex signals
generated by elevated cAMP levels in response to various extracellular
stimuli and the interactions between cAMP and growth factor-mediated
pathways in different cell lineages may be key to our understanding of
hematopoietic homeostasis.
| |
NOTE ADDED IN PROOF |
The readers are referred to two recently published articles describing
the discovery of MAPK scaffolding proteins in mammalian cells:
Schaeffer et al64 and Whitmarsh et al.65
| |
ACKNOWLEDGMENT |
The author thanks Cathy Diec and Min Li for technical assistance; Drs
Melanie Cobb, Channing Der, K.-L. Guan, Gary Johnson, and John Majors
for plasmids; and the Genetics Institute for recombinant human CSF-1. I
also thank Drs Jeffrey Pessin and David States for critical reading of
the manuscript and their suggestions.
| |
FOOTNOTES |
Submitted April 6, 1998;
accepted September 23, 1998.
Supported by an American Cancer Society Institutional Grant No.
(IN-36-34), by a grant-in-aid from the American Heart Association Missouri Affiliate, and by the National Institutes of Health (Grant No.
R01 DK48929).
The publication costs of this
article were defrayed in part by
page charge payment. This article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. section
1734 solely to indicate this fact.
Address reprint requests to Angel Wai-mun Lee, MD, PhD, Department of
Biochemistry and Molecular Biophysics, Washington University Medical
School, Box 8231, 660 S Euclid Ave, St Louis, MO 63110; e-mail:
lee{at}biochem.wustl.edu.
| |
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Abstract
Introduction