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The Journal of Neuroscience, June 1, 1999, 19(11):4211-4220
Mitogenic Signaling by ATP/P2Y Purinergic Receptors in
Astrocytes: Involvement of a Calcium-Independent Protein Kinase C,
Extracellular Signal-Regulated Protein Kinase Pathway Distinct from the
Phosphatidylinositol-Specific Phospholipase C/Calcium Pathway
Joseph T.
Neary,
Yuan
Kang,
Yurong
Bu,
Esther
Yu,
Katherine
Akong, and
Christopher M.
Peters
Research Service, Veterans Affairs Medical Center, and Departments
of Pathology and Biochemistry and Molecular Biology, University of
Miami School of Medicine, Miami, Florida 33125
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ABSTRACT |
Activation of ATP/P2Y purinergic receptors stimulates proliferation
of astrocytes, but the mitogenic signaling pathway linked to these
G-protein-coupled receptors is unknown. We have investigated the role
of extracellular signal-regulated protein kinase (ERK) in P2Y
receptor-stimulated mitogenic signaling as well as the pathway that
couples P2Y receptors to ERK. Downregulation of protein kinase C (PKC)
in primary cultures of rat cerebral cortical astrocytes greatly reduced
the ability of extracellular ATP to stimulate ERK. Because occupancy of
P2Y receptors also leads to inositol phosphate formation, calcium
mobilization, and PKC activation, we explored the possibility that
signaling from P2Y receptors to ERK is mediated by a
phosphatidylinositol-specific phospholipase C (PI-PLC)/calcium pathway.
However, neither inhibition of PI-PLC nor chelation of calcium
significantly reduced ATP-stimulated ERK activity. Moreover, a
preferential inhibitor of calcium-dependent PKC isoforms, Gö
6976, was significantly less effective in blocking ATP-stimulated ERK
activity than GF102903X, an inhibitor of both calcium-dependent and
-independent PKC isoforms. Furthermore, ATP stimulated a rapid
translocation of PKC , a calcium-independent PKC isoform, but not
PKC , a calcium-dependent PKC isoform. ATP also stimulated a rapid
increase in choline, and inhibition of phosphatidylcholine hydrolysis
blocked ATP-evoked ERK activation. These results indicate that P2Y
receptors in astrocytes are coupled independently to PI-PLC/calcium and
ERK pathways and suggest that signaling from P2Y receptors to ERK
involves a calcium-independent PKC isoform and hydrolysis of
phosphatidylcholine by phospholipase D. In addition, we found that
inhibition of ERK activation blocked extracellular ATP-stimulated DNA
synthesis, thereby indicating that the ERK pathway mediates mitogenic
signaling by P2Y receptors.
Key words:
purinergic receptors; MAP kinase; protein kinase C; proliferation; phospholipases; astrocytes
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INTRODUCTION |
Emerging evidence points to a
crucial role for extracellular signal-regulated protein kinases (ERK1
and ERK2) in regulating cellular proliferation and differentiation (for
review, see Marshall, 1995 ; Neary, 1997). ERKs are part of a family of
serine/threonine protein kinases known as mitogen-activated protein
kinases (MAPKs) (Seger and Krebs, 1995). These enzymes are components
of a signaling cascade consisting of at least three cytoplasmic protein
kinases that are activated sequentially. ERKs are activated by
phosphorylation on tyrosine and threonine residues by a
dual-specificity protein kinase termed MAPK/ERK kinase (MEK). MEK in
turn is activated by phosphorylation on serine/threonine residues,
which can be catalyzed either by the Raf family of protein kinases, the
protooncogene product Mos, or MEK kinases (Avruch et al., 1994). The
ERK/MAPK cascade is stimulated shortly after extracellular signals bind to cell surface receptor tyrosine kinases or heterotrimeric
G-protein-coupled receptors (GPCRs). These receptors are linked to the
ERK/MAPK cascade by a sequence of protein-protein interactions and by
upstream protein kinases such as protein kinase C (PKC). The activated ERK can then translocate to the nucleus where it can activate or induce
transcription factors such as Elk-1 and c-Fos (Karin, 1995). In this
manner, ERKs provide a link between cytoplasmic and nuclear signaling,
ultimately leading to changes in gene expression involved in
proliferation and differentiation.
Recent studies on the role of extracellular ATP in the brain have
demonstrated that in addition to serving as an excitatory neurotransmitter (Edwards et al., 1992; Harms et al., 1992; Shen and
North, 1993), ATP can also exert mitogenic and morphogenic activity on
glial and neuronal cells (Neary et al., 1996). For example, treatment
of astrocytes with ATP leads to increases in DNA synthesis (Rathbone et
al., 1992; Abbracchio et al., 1994; Neary et al., 1994b), in process
formation (Neary et al., 1994b) and elongation (Abbracchio et al.,
1994, 1995), and in the content of glial fibrillary acidic protein
(Neary et al., 1994b), an astrocyte-specific marker that is upregulated
after brain injury (Eng, 1988). These trophic actions of ATP may be
important in development and synaptogenesis as well as in tissue injury
and repair, but the signaling mechanisms underlying the trophic
activity of ATP are unknown.
The biological actions of extracellular ATP are mediated by cell
surface receptors designated as P2 purinoceptors (Burnstock, 1978).
This general class of receptors has been categorized into two major
types: ligand-gated ionotropic receptors (P2X) and G-protein-coupled metabotropic receptors (P2Y) (Abbracchio and Burnstock, 1994). P2Y
receptors are expressed in astrocytes, and these receptors are coupled
to phosphatidylinositol-specific phospholipase C (PI-PLC), leading to
inositol phosphate formation and calcium mobilization (Pearce et al.,
1989; Neary et al., 1991; Kastritsis et al., 1992; Salter and Hicks,
1994, 1995; King et al., 1996; Centemeri et al., 1997). After
activation of the PI-PLC/calcium pathway, PKC is then activated.
We have shown that P2Y receptors in astrocytes are also linked to the
ERK/MAPK cascade (Neary and Zhu, 1994; King et al., 1996). However, the
signaling elements that couple the P2Y receptors to the ERK/MAPK
cascade have not been defined. Preliminary evidence indicates that
signaling from P2Y receptors to ERK in astrocytes is dependent on PKC
(Neary, 1996). Because P2Y receptor signaling can involve PKC in both
PI-PLC and ERK pathways, we have investigated the hypothesis that
PI-PLC/calcium are upstream of ERK. We report here for the first time
that P2Y receptors are coupled independently to PI-PLC and ERK pathways
and that the latter pathway involves hydrolysis of phosphatidylcholine
(PC) and a calcium-independent isoform of PKC. We also provide evidence
that the ERK pathway mediates ATP-induced mitogenic signaling in astrocytes.
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MATERIALS AND METHODS |
Cell culture and treatment. Primary astrocytes were
obtained from neonatal rat (Fischer) cerebral cortices as described
previously (Neary et al., 1994a). Cells were seeded at densities of
150,000 cells/well in 24-well plates (for DNA synthesis studies) or at 300,000 cells/35 mm or 600,000 cells/60 mm plates (for ERK studies); cells were not replated before use. At least 99% of the cell
population were astrocytes, as determined by staining with
cell-specific markers (Neary et al., 1994a). Experiments were conducted
with 3- to 6-week-old cultures. Before treatment with nucleotides or other agents, cells that had been maintained in DMEM containing 10%
horse serum were shifted to the quiescent phase by incubation in
DMEM containing 0.5% horse serum for 48-72 hr. Stock solutions of nucleotides and drugs were divided into single-use aliquots and
stored at  80°C, except for D609 (Research Biochemicals
International, Natick, MA), which was prepared fresh for each experiment.
DNA synthesis. 3H-thymidine incorporation was
measured as described previously (Neary et al., 1994a) using confluent
cells in the stationary phase of growth. In brief, nucleotides or PD 098059 (Research Biochemicals International) or both at the indicated final concentrations were added to the media in the wells in triplicate or quadruplicate. PD 098059 was added 60 min before addition of nucleotides. As a positive control, some wells were treated with 10%
horse serum, whereas untreated cultures were used for negative controls. After 18 hr, 3H-thymidine (0.5 µCi/ml culture
media; 83 Ci/mmol; ICN Biochemicals, Costa Mesa, CA) was added to the
media in the wells for an additional 4 hr. Cells were then rinsed with
Dulbecco's PBS (D-PBS), incubated in 10% trichloroacetic acid
for 30 min on ice, rinsed again with D-PBS, and lysed in 1% SDS, 0.3 N
NaOH. Aliquots were neutralized and counted by liquid scintillation spectrometry.
ERK activity. After treatment with nucleotides or other
agents for the times and concentrations indicated, cells were rinsed quickly in ice-cold D-PBS and lysed in a buffer containing 20 mM Tris, pH 7.0, 0.27 M sucrose, 1 mM EDTA, 1 mM EGTA, 50 mM NaF, 1 mM dithiothreitol (DTT), 1 mM sodium
orthovanadate, 10 mM  -glycerophosphate, 5 mM
sodium pyrophosphate, and 1% Triton X-100. In some cases, cells were
lysed in a buffer containing 20 mM Tris, pH 7.5, 100 mM NaCl, 50 mM NaF, 2 mM EGTA, 50 mM -glycerophosphate, 1 mM sodium
orthovanadate, 100 µg/ml 4-(2-aminoethyl) benzenesulfonylfluoride (AEBSF; Calbiochem, La Jolla, CA), 0.3 U/ml aprotinin, and 1% Triton
X-100. The lysates were centrifuged in a microfuge for 5 min at 4°C.
ERK activity was measured as described previously (Neary and Zhu,
1994). In brief, aliquots (20 µl containing 10-20 µg protein) of
the supernatants were assayed at 30°C for 20 min in a final reaction
solution containing 10 µM ATP (0.2 µCi
[32P]ATP; 3000 Ci/mmol; New England Nuclear), 10 mM MgCl2, 1 µM okadaic acid, and 0.33 mg/ml bovine brain myelin basic protein (MBP) in a final
volume of 40 µl. Under these conditions, the reaction is linear with
respect to time and enzyme concentration. Reactions were stopped by
pipetting 20 µl aliquots onto 1 × 2 cm strips of
phosphocellulose paper (Sevetson et al., 1993) and immediately placing
the strips in 75 mM phosphoric acid. Strips were washed for
a minimum of 2 hr and rinsed three times for 5 min each in 75 mM phosphoric acid and once in ethanol. Strips were dried
and transferred to scintillation vials, and radioactivity was assessed by liquid scintillation counting. ERK activity was expressed as picomoles of 32P transferred per minute per milligram of
protein. Protein concentrations were determined by the modified Lowry
procedure as described (Peterson, 1983), with bovine serum albumin as
standard. The validity of the phosphocellulose strip assay under these
conditions was confirmed by comparing the data with phosphorylation of
MBP obtained by SDS-PAGE of the samples followed by autoradiography and
densitometry (Bio-Rad GS-670 imaging densitometer; Bio-Rad, Hercules,
CA); a correlation coefficient of 0.935 was obtained (Neary and Zhu, 1994). Results obtained by this procedure were consistent with those
obtained by immunocomplex kinase assays after immunoprecipitation with
anti-ERK1/2 (Santa Cruz Biotechnology, Santa Cruz, CA) as described
previously (Neary and Zhu, 1994) or by determination of phosphorylated
ERK1/2 as described below.
Anion exchange chromatography. The procedure of Ahn et al.
(1990) was used with some modifications. After treatment of cultures with ATP (six 60 mm plates per group), plates were rinsed quickly in
ice-cold PBS. Cells were scraped and homogenized in buffer A (50 mM -glycerophosphate, pH 7.3, 0.1 mM sodium
orthovanadate, 1.5 mM EGTA, 1 mM DTT), and the
homogenate was centrifuged at 13,000 × g for 10 min at
4°C. Supernatants were stored at 70°C. Before chromatography,
supernatants were thawed and centrifuged for 30 min at 23,000 × g, 4°C. Supernatants containing equivalent amounts of
protein were loaded onto a 1 ml Hi-Trap Q (Amersham Pharmacia Biotech)
column at a flow rate of 0.5 ml/min. Fractions (1 ml) were collected
with a Gradifrac protein purification system (Amersham Pharmacia
Biotech), and the column was washed with 8 ml buffer A. Elution was
conducted with a 60 ml, linear NaCl gradient (0-400 mM
NaCl in buffer A). Fractions (20 µl) were assayed for ERK activity as
described above using MBP as substrate. In addition, ERK1/2 was
detected in column fractions and cellular extracts by immunoblotting as
described below.
Membrane preparation. After quiescent cultures were treated
with ATP or 12-O-tetradecanoylphorbol-13-acetate (TPA) for
the time periods indicated in the text, cells were quickly rinsed twice
with ice-cold PBS and collected in 200 µl (per 35 mm plate; four
plates/group) of a buffer containing 50 mM Tris, pH 7.7, 2 mM EGTA, 5 mM DTT, 100 µg/ml AEBSF, and 10 µg/ml leupeptin. Cells were homogenized (20 strokes) using a
Teflon-glass homogenizer, and homogenates were centrifuged at
100,00 × g for 60 min, 4°C, in a Beckman TL-100
centrifuge. Pellets were suspended in 800 µl of the homogenizing
buffer containing 1% Triton X-100. Suspensions were incubated on ice
for 30 min and sonicated for 5-10 sec (Ultrasonic 40W, Heat Systems,
Farmingdale, NY). Protein concentrations were determined by the
modified Lowry procedure (Peterson, 1983). Fractions were diluted in
2× Laemmli SDS sample buffer (Laemmli, 1970) and heated in a boiling
water bath for 5 min.
Immunoblotting. Samples containing equal amounts of protein
were subjected to SDS-PAGE (Laemmli, 1970) using 11% acrylamide and
transferred to nitrocellulose filters with a Genie electrophoretic blotter (Idea Scientific, Minneapolis, MN) for 1 hr at 12 V in a
transfer buffer containing 25 mM Tris, 192 mM
glycine, and 20% methanol. Filters were incubated with a blocking
solution containing 20 mM Tris, pH 7.7, 137 mM
NaCl, 0.1% Tween 20 (TTBS), and 5% nonfat dry milk for 1 hr at room
temperature, rinsed in TTBS, and then incubated for 1 hr at room
temperature with specific antibodies diluted in TTBS
[anti-phospho-ERK1/2 (1/20,000; Promega, Madison, WI), anti-ERK1/2
(1/500; Santa Cruz Biotechnology), anti-PKC (1/200; Transduction
Laboratories, Lexington, KY), or anti-PKC (1/5000; Transduction
Laboratories)]. After three rinses in TTBS, filters were incubated for
1 hr at room temperature with peroxidase-conjugated anti-rabbit or
anti-mouse IgG diluted in TTBS (1/20,000 or 1/10,000, respectively;
Amersham Life Sciences, Arlington Heights, IL). Filters were washed
three times in TTBS, and proteins were detected by enhanced
chemiluminescence (Amersham Life Sciences).
Inositol phosphate formation. Inositol phosphates were
measured by a previously described procedure that involves prelabeling cells overnight with myo-[2-3H(N)]inositol
(12.3Ci/mmol; New England Nuclear), stimulating with ATP as described
in the text, applying aqueous extracts to Dowex AG 1-X8 columns, and
eluting inositol phosphates with 1 M ammonium formate/0.1
M formic acid (Bender et al., 1993). The 3H
recovered in inositol phosphates was then standardized to an incorporation of 105 cpm in the lipid fraction.
PC hydrolysis. Cells were incubated with
3H-choline, and water-soluble
3H-choline-labeled metabolites were separated and
quantitated as described (Vance et al., 1980) with some modifications.
In brief, cultures grown on 35 mm dishes were incubated in DMEM/0.5%
horse serum containing 2.5 µCi [methyl-3H]-choline
(NEN; 60-90 Ci/mmol)/ml for 48 hr followed by a 24 hr incubation in
DMEM/0.5% horse serum. After treatment with ATP for the times
indicated, the media was quickly removed, and 2.1 ml of extraction
solution (methanol/10 mM glycine, pH 3.0; 5:2, v/v) was
added immediately. Dishes were scraped, and the extract was transferred
to 15 ml centrifuge tubes. Chloroform (0.8 ml) was added, tubes were
vortexed, 0.8 ml water and 0.8 ml chloroform were added, tubes were
vortexed again, and phases were separated by centrifugation at 660 × g for 5 min. The lipid phase was removed, and the aqueous
phase was re-extracted with 0.8 ml chloroform, followed by vortexing
and centrifugation as described above. Aqueous phases were combined,
and carrier choline, phosphocholine, cytidine 5'-diphospho-choline, and
glycerophosphocholine (50 µg each) were added to a 0.5 ml aliquot
that was concentrated to 25 µl by vacuum centrifugation. Samples were
applied to a silica gel thin layer plate that was developed in 0.5%
NaCl, ethanol, methanol, NH4OH (5:3:2:0.5; v/v). The plate
was dried at room temperature, and spots were detected by iodine vapor,
scraped into scintillation vials containing 0.75 ml 0.1N NaOH, and
incubated overnight at room temperature. Acetic acid (75 µl of 1.5N)
was added to each vial, and radioactivity was determined by
scintillation spectrometry. The 3H recovered in the
choline-containing fractions was then standardized to an incorporation
of 105 cpm in the aqueous phase.
Statistical analyses. All experiments were conducted a
minimum of three times, each time with cultures from different
seedings. Data were analyzed by Student's t tests for two
groups or ANOVA followed by post hoc comparisons for
multiple groups with an Instat software package (GraphPad Software).
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RESULTS |
Signaling from ATP/P2Y receptors to ERK in astrocytes is dependent
on PKC
P2Y receptors are members of the heterotrimeric GPCR superfamily
(Abbracchio and Burnstock, 1994). Signaling from GPCRs to the ERK/MAPK
cascade can proceed by several distinct pathways, some of which involve
PKC (van Biesen et al., 1996b; Neary, 1997). To determine whether
signaling from astrocytic P2Y receptors to ERK is dependent on PKC,
primary cultures of rat cortical astrocytes were treated overnight with
phorbol ester (TPA; 100 nM) to downregulate PKC; such
chronic treatment with TPA reduces PKC activity in astrocytes by at
least 90% (Neary et al., 1988). After addition of extracellular ATP,
cellular homogenates were then prepared and fractionated by anion
exchange chromatography under conditions that separate p42 and p44
isoforms of ERK (Ahn et al., 1990). After stimulation of astrocytes
with ATP (100 µM, 15 min), two peaks of ERK activity were
eluted at ~110 and 175 mM NaCl (Fig.
1). Downregulation of PKC by chronic
phorbol ester treatment reduced the ability of extracellular ATP to
stimulate the two regions of ERK activity by ~85% (Fig. 1). To
confirm the presence of ERK in these two regions of activity,
immunoblots of peak fractions and of a fraction between the peaks were
probed with an antibody that recognizes both ERK1 and ERK2. As shown in
the inset of Figure 1, the first peak contained ERK2 and the second
peak contained ERK1. In separate experiments, astrocytes were treated
acutely with phorbol ester (100 nM, 5 min); ERK activity
was stimulated 2.95 ± 0.13-fold, thereby indicating that PKC can
activate ERK in astrocytes.
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Figure 1.
Signaling from P2Y receptors to ERK is dependent
on PKC. Primary rat astrocyte cultures were treated with 100 µM ATP for 15 min ( -), with 100 nM TPA
for 24 hr before application of 100 µM ATP for 15 min
( -), or were untreated (×-×). Homogenates were centrifuged,
and supernatants containing equivalent amounts of protein were applied
to a 1 ml Hi-Trap Q anion exchange column as described in Materials and
Methods. Fractions (1 ml) were collected at a flow rate of 0.5 ml/min,
and proteins were eluted with a linear, 60 ml NaCl gradient (0-400
mM). Two peaks of ERK activity eluted at 110 and 175 mM NaCl. Inset, Immunoblot of column
fractions from the peak ERK regions and a fraction between the peaks.
The indicated column fractions and the cellular extract
(EXT) from the ATP-treated, normal cells were
subjected to SDS-PAGE, and immunoblots were probed with anti-ERK1/2.
The arrows indicate the two ERK isoforms p42 and p44,
before and after fractionation by anion exchange chromatography.
Similar results were obtained by chromatography on a 1 ml Resource Q
(Amersham Pharmacia Biotech) column.
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Inhibition of PI-PLC or chelation of calcium does not block
ATP-stimulated ERK activation
In astrocytes as in other cells, activation of P2Y receptors leads
to mobilization of intracellular calcium via the PI-PLC pathway; the
increased calcium, together with the PI-PLC-catalyzed increase in
diacylglycerol, can then activate PKC. The finding that signaling from
P2Y receptors to ERK is dependent on PKC raised the possibility that
PI-PLC, calcium, PKC, and ERK are part of the same signal transduction
pathway. To determine whether PI-PLC and calcium are upstream of ERK,
several approaches were used. To block signaling from P2Y receptors to
ERK via PI-PLC, we used an inhibitor of PI-PLC, the steroidalamine
U73122 (Bleasdale et al., 1990; Salter and Hicks, 1995). Cultures were
treated with U73122 (10 µM) for 30 min before application
of extracellular ATP, after which ERK activity and inositol phosphate
formation were measured. As shown in Figure
2A, U73122 did not
diminish the ability of ATP to activate ERK. However, U73122 was
effective in blocking ATP-evoked inositol phosphate formation (Fig.
2B). These findings suggest that activation of ERK by
stimulation of P2Y receptors can proceed independently of the PI-PLC
pathway.
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Figure 2.
Inhibition of PI-specific PLC does not block
ATP-stimulated ERK activity. In A, primary rat astrocyte
cultures were treated with 10 µM U73122 for 30 min before
addition of ATP (100 µM, 15 min). ERK activity data
(mean ± SEM) were obtained from three experiments, each conducted
with duplicate culture plates. ERK activity in untreated cultures was
43.5 ± 8.2 pmol phosphate transferred per minute per milligram of
protein. In B, primary rat astrocyte cultures were
treated with 10 µM U73122 for 30 min before addition of
ATP (500 µM, 30 min), and inositol phosphates were
extracted and measured as described in Materials and Methods.
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The ability of extracellular ATP to stimulate ERK independently of
PI-PLC suggests that calcium mobilization is not required for
activation of ERK by P2Y receptors. To test this, we used BAPTA-AM to
chelate intracellular calcium. Treatment of cells with 30 µM BAPTA-AM for 30 min before application of ATP did not significantly reduce ERK activation (fold-stimulation: ATP, 2.64 ± 0.05; BAPTA + ATP, 2.68 ± 0.12; p > 0.05). As
another approach, EGTA was used to minimize entry of extracellular
calcium across the plasma membrane, an event that can occur in response
to depletion of intracellular stores after application of ATP. However,
treatment with 3 mM EGTA for 5 min, a condition known to
block carbachol- and bradykinin-evoked activation of ERK (Lev et al.,
1995), did not significantly reduce ATP-stimulated ERK activity
(fold-stimulation: ATP, 2.57 ± 0.25; EGTA + ATP, 2.47 ± 0.20; p > 0.05).
A calcium-independent PKC isoform mediates signaling from P2Y
receptors to ERK
Because P2Y receptor signaling to ERK is independent of PI-PLC and
calcium, but dependent on PKC, we reasoned that a calcium-independent isoform of PKC may be involved in the P2Y/ERK pathway. If this is the
case, a preferential inhibitor of calcium-dependent PKCs, Gö 6976 (Martiny-Baron et al., 1993), should have less of an effect on the
stimulation of ERK by agonists of P2Y receptors than GF102903X, an
inhibitor of both calcium-dependent and independent PKCs. To test this,
cultures were treated with varying concentrations (1, 2.5, or 5 µM) of Gö 6976 or GF102903X for 20 min before
addition of ATP (100 µM; 5 min). As shown in Figure
3A, Gö 6976 was
less effective than GF102903X in inhibiting ATP stimulation of ERK activity. The greater degree of inhibition observed with GF109203X was
significantly different from that observed with Gö 6976 for each
of the concentrations used (p < 0.01). To
confirm this observation, we tested the effect of these inhibitors on
ATP-evoked ERK phosphorylation, which was measured by immunoblot
analysis with an antibody that recognizes dually phosphorylated ERK1
and ERK2 (Thr183, Tyr185). As
shown in Figure 3B, phosphorylation of ERK1 and ERK2 was only slightly reduced by Gö 6976, whereas GF102903X almost
completely blocked ATP-evoked phosphorylation. These experiments
support the concept that P2Y receptors are coupled to ERK by a
calcium-independent isoform of PKC.
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Figure 3.
Effects of inhibitors of calcium-independent and
-dependent PKC isoforms on signaling from P2Y receptors to ERK. In
A, primary rat astrocyte cultures were treated with ATP
(100 µM, 5 min) or with Gö 6976 (1-5
µM, 20 min), which preferentially inhibits
calcium-dependent PKC isoforms, or GF109203X (1-5 µM, 20 min), an inhibitor of both calcium-dependent and -independent PKC
isoforms, before addition of ATP (100 µM, 5 min). ERK
activity data were obtained from a minimum of three experiments, each
conducted with duplicate culture plates. In B, primary
rat astrocyte cultures were treated with ATP (100 µM, 5 min) or with Gö 6976 (2.5 µM) or GF109203X (2.5 µM) for 20 min before addition of ATP (100 µM, 5 min), cells were lysed, and lysates containing
equivalent amounts of protein were subjected to SDS-PAGE. Immunoblots
were probed with antibodies that recognize phosphorylated ERK1/ERK2
(top panel) or ERK1/ERK2 (bottom
panel).
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To determine whether activation of P2Y receptors leads to translocation
of a calcium-independent PKC isoform, membrane fractions from untreated
and ATP-treated astrocytes were immunoblotted and probed with
antibodies raised against PKC, a calcium-independent PKC isoform
present in astrocytes (Gott et al., 1994). For comparison, translocation of PKC, a calcium-dependent PKC isoform, was also examined. As shown in Figure
4A, ATP stimulated a
rapid translocation (15 sec) of PKC, but not PKC. By contrast,
PKC was translocated by a phorbol ester TPA (100 nM, 5 min) (Fig. 4A). Time course studies revealed that
ATP-evoked translocation of PKC was observed at 5 sec, reached a
peak at 15 sec, and declined from 30 to 60 sec (Fig.
4B). This rapid translocation of PKC can be
compared with time course studies of ERK activation, which showed that ATP-stimulated ERK activity was detected at 1.5 min (Neary and Zhu,
1994), thereby indicating that PKC translocation occurs before ERK
activation.
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Figure 4.
Extracellular ATP stimulates translocation of a
calcium-independent PKC isoform. In A, primary rat
astrocyte cultures were treated with or without
(CON) 100 µM ATP for 15 sec, or
with 100 nM TPA for 5 min, and particulate fractions were
prepared as described in Materials and Methods. Equal amounts of
protein (3.9 µg) were subjected to SDS-PAGE and analyzed by
immunoblotting with monoclonal antibodies raised against PKC or
PKC. In B, astrocytes were treated with 100 µM ATP for the times indicated, and particulate fractions
were obtained. Equal amounts of protein within each experiment (ranging
from 4 to 5 µg) were analyzed by immunoblotting with a monoclonal
antibody raised against PKC. Values given are mean ± SEM;
densitometric analysis (Bio-Rad GS-670) was conducted on a minimum of
four to six independent experiments, each representing different
culture seedings.
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Signaling from P2Y receptors to ERK is dependent on hydrolysis
of phosphatidylcholine
If P2Y receptors signal to ERK by a pathway that involves a
calcium-independent PKC and is independent of PI hydrolysis, we reasoned that the diacylglycerol needed to activate PKC may come from
the hydrolysis of PC. To test this, time course studies were conducted
to examine the ability of ATP to stimulate PC hydrolysis. We found that
treatment of cultures with ATP led to the production of choline, which
was observed at 15 sec and peaked at 30 to 60 sec (Fig.
5). This finding, together with a lack of
increase in phosphocholine (data not shown), suggests that astrocytic
P2Y receptors are coupled to phospholipase D (PLD) rather than
PC-specific PLC. The time course of choline formation is consistent
with the rapid translocation of PKC and subsequent activation of
ERK.
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Figure 5.
Extracellular ATP rapidly stimulates choline
formation. Primary rat astrocyte cultures were incubated with
3H-choline (2.5 µCi/ml) for 48 hr followed by 24 hr in
choline-free culture medium before treatment with ATP (100 µM) for the indicated times. Choline formation was
measured as described in Materials and Methods. Similar results were
obtained in two additional experiments.
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To determine whether PC hydrolysis is upstream of ERK activation, we
used tricyclodecan-9-yl-xanthogenate (D609), which inhibits the
hydrolysis of PC but not PI (Muller-Decker, 1989; Schutze et al., 1992;
Cai et al., 1993; Inui et al., 1994; Kiss and Tomono, 1995; van Dijk et
al., 1997). Cultures were treated with D609 for 60 min before
stimulation by ATP (100 µM, 5 min). We found that D609
inhibited ATP-stimulated phosphorylation of ERK1 and ERK2 (Fig.
6A) and ERK activity
(Fig. 6B) in a dose-dependent manner. At 50 µg/ml
D609, a concentration frequently used to inhibit PC hydrolysis and
diacyglycerol formation in intact cells (Muller-Decker, 1989; Schutze
et al., 1992; Inui et al., 1994; Kiss and Tomono, 1995), ATP-stimulated
ERK activity was reduced by ~75%, thereby indicating that signaling
from P2Y receptors to ERK involves PC hydrolysis.
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Figure 6.
Inhibition of PC hydrolysis decreases the ability
of ATP to stimulate ERK activity. Primary rat astrocytes were treated
without or with the indicated concentrations of D609 for 60 min before
addition of ATP (100 µM) for 5 min. In A,
phosphorylated ERK1/ERK2 (top panel) and
ERK1/ERK2 (bottom panel) were detected by
immunoblotting as described in Materials and Methods. In
B, ERK activity data (mean ± SEM) were obtained
from three independent experiments, each representing different
seedings and conducted with duplicate culture plates. "0" indicates
cultures treated with ATP only. ERK activity in untreated cultures was
43.3 ± 4.9 pmol phosphate transferred per minute per milligram of
protein. **p < 0.001; *p < 0.05 for comparisons of ATP versus D609 + ATP.
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Signaling from P2Y receptors to ERK via pertussis toxin-sensitive
and -insensitive G-proteins
The type(s) of G-proteins involved in the P2Y/ERK pathway was
studied by using pertussis toxin; this agent inactivates  subunits of the Gi and Go families but does not affect
Gs or Gq subunits (Yahame and Fung, 1993).
Cultures were treated with 100 ng/ml pertussis toxin overnight (18-20
hr) before addition of ATP (100 µM) for 5 min. We found
that pertussis toxin diminished the ability of ATP to stimulate ERK
activity by 68 ± 3% (mean ± SEM; p < 0.0001; n = 8). These results suggest that coupling of
P2Y receptors in astrocytes to the ERK/MAPK cascade is mainly via
pertussis toxin-sensitive G-proteins.
Role of the ERK/MAPK cascade in mediating mitogenic signaling by
P2Y receptors
To determine whether the ERK/MAPK cascade is involved in
extracellular ATP-induced mitogenesis, we used PD 098059 [2-(2'amino-3'methoxypheny)-oxanaphthalen-4-one], a selective
inhibitor of MEK1 that was shown to inhibit growth factor-induced DNA
synthesis without altering cell viability (Dudley et al., 1995). First,
we examined the ability of PD 098059 to inhibit activation of ERK by
extracellular ATP. Primary cultures of astrocytes were treated with PD
098059 (50 µM) for 30 min before addition of ATP (100 µM, 5 min), cellular lysates were subjected to SDS-PAGE,
and phosphorylated ERK1 and ERK2 were detected by immunoblot analysis.
As shown in Figure 7A, PD
098059 greatly reduced extracellular ATP-evoked phosphorylation of ERK1
and ERK2. ERK activity assays confirmed this finding (data not shown).
We then investigated the ability of PD 098059 to inhibit ATP-induced mitogenic signaling. Primary cultures of astrocytes were treated with
PD 098059 (50 µM) for 30 min before the addition of ATP
(100 µM), and its effect on ATP-induced DNA synthesis was
measured. As shown in Figure 7B, PD 098059 blocked the
ability of ATP to stimulate DNA synthesis. Additional experiments
demonstrated that 50 µM PD 098059 did not affect cellular
viability as assessed by measuring protein synthesis
(3H-leucine incorporation; data not shown). These results
demonstrate that the ERK/MAPK cascade mediates mitogenic signaling by
P2Y receptors.
View larger version (54K):
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|
Figure 7.
Extracellular ATP-evoked mitogenic signaling is
mediated by the ERK/MAPK cascade. In A, primary rat
astrocyte cultures were treated with ATP (100 µM, 5 min),
or with PD 098059 (50 µM) for 30 min before addition of
ATP (100 µM, 5 min), cells were lysed, and lysates
containing equivalent amounts of protein were subjected to SDS-PAGE.
Immunoblots were probed with antibodies that recognize phosphorylated
ERK1/ERK2 (top panel) or ERK1/ERK2 (bottom
panel). In B, primary rat astrocyte
cultures were treated with ATP (100 µM), or with PD
098059 (50 µM) for 30 min before addition of ATP, and DNA
synthesis was determined as described in Materials and Methods. Values
are given as the mean ± SE of the mean and were obtained from
three independent experiments, each conducted in quadruplicate and with
different seedings. 3H-thymidine incorporation in untreated
cultures was 1055 ± 358 cpm per culture well.
*p < 0.001 for comparison of ATP versus PD 098059 + ATP.
|
|
| |
DISCUSSION |
The main findings of the studies presented here are that (1)
signaling from P2Y receptors to ERK is independent of the
PI-PLC/calcium pathway and involves a calcium-independent PKC isoform
as well as PC hydrolysis, which may be catalyzed by PLD, and (2) the
ERK/MAPK cascade mediates mitogenic signaling by P2Y receptors.
Components of the signaling pathway from P2Y purinergic receptors
to the ERK/MAPK cascade in primary cultures of rat cortical
astrocytes
The role of PKC in GPCR/ERK signaling pathways has not been
completely defined. In some cases, GPCRs can be coupled to ERK by both
PKC-dependent and -independent pathways, thereby suggesting multiple
signaling pathways from a specific receptor to ERK. For example,
signaling from endothelin-1 receptors to ERK was reduced ~50% by
chronic phorbol ester treatment in mesangial cells (Wang et al., 1992),
cardiac myocytes (Bogoyevitch et al., 1994), and astrocytes (Cazaubon
et al., 1993). The studies presented here indicate that PKC is a
crucial element of the pathway linking P2Y receptors to the ERK/MAPK
cascade in primary cultures of cortical astrocytes because inhibition
or downregulation of PKC reduced the ability of extracellular ATP to
stimulate ERK activity by ~90%. To our knowledge, these studies are
the first to document in brain cells that PKC is upstream of ERK in
this P2Y receptor signaling pathway.
It is well established that P2Y receptors in astrocytes are also
coupled to PI-PLC (Pearce et al., 1989; Neary et al., 1991; Kastritsis
et al., 1992; Salter and Hicks, 1994, 1995; King et al., 1996;
Centemeri et al., 1997). Because signaling from P2Y receptors to ERK is
dependent on PKC, this raised the possibility that P2Y receptors signal
to ERK via PI-PLC. However, evidence presented here indicates that this
is not the case. Inhibition of PI-PLC blocked the ability of
extracellular ATP to stimulate formation of inositol phosphates but did
not significantly reduce activation of ERK, thereby indicating that P2Y
receptors are coupled independently to PI-PLC and ERK. Moreover,
chelation of intracellular or extracellular calcium did not decrease
the ability of extracellular ATP to activate ERK, thereby suggesting
that calcium-dependent protein kinases such as Pyk2 (Lev et al., 1995)
or calcium-dependent isoforms of PKC are not upstream of ERK.
Consistent with this was the finding that Gö 6976, which
preferentially inhibits calcium-dependent PKC isoforms
(Martiny-Baron et al., 1993), was significantly less effective in
reducing the ability of extracellular ATP to activate ERK than
GF10290X, an inhibitor of both calcium-dependent and -independent
PKC isoforms. A previous study using the PKC inhibitor CGP 41251, which
displays selectivity for calcium-dependent PKC isoforms, implicated the
involvement of a calcium-independent PKC isoform in signaling from P2Y
receptors to ERK in renal mesangial cells, but this report did not
examine PKC translocation induced by ATP (Huwiler and Pfeilschifter,
1994). Here we have found that a calcium-independent isoform, PKC,
was rapidly translocated from the cytosol to the membrane on
stimulation of P2Y receptors, and this translocation occurred before
ERK activation. Although studies with antisense oligonucleotides or
dominant negative mutants are needed to further establish the role of
PKC, our findings in primary cells are in agreement with a recent
report using COS cells in which overexpression of a
constitutively active mutant of PKC was sufficient to activate MEK
and ERK (Ueda et al., 1996). Overexpression of another
calcium-dependent isoform, PKC , or a calcium-dependent isoform,
PKC, did not activate MEK or ERK. In addition, PKC-evoked
activation of MEK and ERK was not blocked by overexpression of an
inactive mutant of Ras, thereby indicating that PKC can activate the
ERK/MAPK cascade in a manner independent of Ras. Previous studies
suggest that signaling from P2Y receptors to ERK in astrocytes does not
involve Ras (Neary and Zhu, 1994; Neary, 1996).
Because a calcium-independent PKC isoform mediates signaling from P2Y
receptors to the ERK/MAPK cascade in primary cultures of rat cortical
astrocytes, we investigated the possibility that P2Y receptors are
coupled to ERK by phospholipases that are not directly linked to
calcium signaling and yet can generate diacylglycerol for PKC
activation. PC-PLC and PLD are two such enzymes that have been
implicated in mitogenesis (Cai et al., 1993; Boarder, 1994). Hydrolysis
of PC by PC-PLC yields diacylglycerol, which can then activate PKC
isoforms. Alternatively, PC hydrolysis by PLD generates choline and
phosphatidic acid; the latter can be converted to diacylglycerol by
phosphatidic acid phosphohydrolase. Because ATP stimulated a rapid
formation of choline rather than phosphocholine, PLD rather than PC-PLC
may catalyze PC hydrolysis after occupancy of P2Y receptors. Previous
studies have reported that P2Y receptors are linked to PLD in
astrocytes (Gustavsson et al., 1993) as well as endothelial cells
(Martin and Michaelis, 1989; Pirotton et al., 1990; Purkiss and
Boarder, 1992), promyelocytic leukemia cells (Xie et al., 1991), renal
mesangial cells (Pfeilschifter and Merriweather, 1993), and canine
kidney cells (Balboa et al., 1994). However, no information is
available on the role of PLD-catalyzed PC hydrolysis in coupling P2Y
receptors to the ERK/MAPK cascade.
To determine the involvement of PC hydrolysis in signaling from P2Y
receptors to ERK, we used an inhibitor of PC hydrolysis and
diacylglycerol production, D609 (Muller-Decker, 1989; Schutze et al.,
1992; Cai et al., 1993; Inui et al., 1994; Kiss and Tomono, 1995; van
Dijk et al., 1997). Studies with this inhibitor have shown that PC
hydrolysis is upstream of the ERK/MAPK cascade in some signaling
systems. For example, in NIH 3T3 cells, D609 inhibited EGF-, TPA-, and
serum-evoked phosphorylation of Raf (Cai et al., 1993). In Rat-1
fibroblasts, D609 inhibited PDGF-induced activation of ERK, but
EGF-induced activation of ERK was unaffected by D609 (van Dijk et al.,
1997). Expression of the G-protein-coupled 5-HT1A receptor in Chinese
hamster ovary cells promoted activation of ERK2, and this activation
was partially inhibited by D609 (Cowen et al., 1996). As reported here,
we found that D609 inhibited extracellular ATP stimulation of ERK
activity, thereby indicating for the first time that PC hydrolysis
plays an important role in coupling P2Y receptors to the ERK/MAPK cascade.
Inhibition of the ATP-evoked activation of ERK/MAPK by pertussis toxin
suggests that the response is mediated at least in part by G
subunits such as Gi or Go, which are
sensitive to pertussis toxin. By contrast, previous work has shown that
pertussis toxin does not affect ATP-evoked mobilization of
intracellular calcium in astrocytes from rat cerebral cortex (Bruner
and Murphy, 1993a,b) and spinal cord (Ho et al., 1995; Salter and
Hicks, 1995), thereby indicating that signaling from P2Y receptors to
PI-PLC involves a G-protein insensitive to pertussis toxin, such as
Gq/G11 subclass, which lacks a site for
ADP ribosylation. Our finding that the coupling of P2Y receptors to the
ERK/MAPK cascade is not dependent on PI-PLC is consistent with these
results because if PI-PLC were involved in signaling from P2Y receptors
to ERK, pertussis toxin would not be expected to diminish the ability
of ATP to activate ERK. Instead, we found that signaling from P2Y
receptors to ERK was reduced by 65-70%, thereby suggesting the
involvement of a pertussis toxin-sensitive G-protein. Interestingly,
pertussis toxin did not inhibit hypo-osmotic activation of ERK in
astrocytes; in this case, ERK activation was dependent on calcium but
independent of PKC (Schliess et al., 1996). Thus, hypo-osmotic
signaling to the ERK/MAPK cascade in astrocytes differs markedly from
the P2Y/ERK pathway, because in the latter case our findings indicate
that signaling is dependent on PKC, independent of calcium, and
partially blocked by pertussis toxin. The pertussis toxin-sensitive
protein involved in signaling from P2Y receptors to the ERK/MAPK
cascade may be Gi or Go. On the basis of the
findings of van Biesen et al. (1996a), we speculate that Go
is more likely to be implicated because coupling of GPCRs to the
ERK/MAPK cascade by Gi involved a protein tyrosine kinase
but not PKC, whereas coupling of GPCRs to the ERK/MAPK cascade via PKC
involved a Go protein.
As demonstrated here, signaling from P2Y receptors to the ERK cascade
in astrocytes is independent of the PI-PLC/calcium pathway. Activation
of signaling pathways by GPCRs may depend on the type of G-protein that
links receptors to specific effectors, e.g., P2Y receptors may be
coupled to PI-PLC via Gq and to ERK signaling via
Go or Gi. Another possibility is that because
four subtypes of P2Y receptors, P2Y1,
P2Y2, P2Y4, and
P2Y6, have been cloned from rat tissues, ERK and
PI-PLC pathways could be activated by separate subtypes. The P2Y
receptor agonists ATP, UTP, and 2-methylthio-ATP (2-MeSATP) stimulate
both calcium mobilization and ERK activation in rat cortical astrocytes
(King et al., 1996). This suggests that receptor subtypes such as
P2Y1 (2-MeSATP- and ATP-preferring), P2Y2 and
P2Y4 (ATP- and UTP-preferring), and P2Y6
(UTP-preferring) may be coupled to both pathways. However, further
studies are needed to determine the array of P2Y receptor subtypes
expressed in astrocytes and their linkage to specific signaling
pathways. Such efforts would be aided by the development of highly
selective agonists and antagonists to distinguish between endogenous
P2Y receptor subtypes.
The ERK/MAPK cascade mediates mitogenic signaling by ATP/P2Y
receptors in astrocytes
Recent studies have demonstrated the importance of the ERK/MAPK
cascade in cellular proliferation and differentiation (for review, see
Marshall, 1995; Seger and Krebs, 1995). Much of the evidence for the
critical role of the ERK/MAPK cascade in cell growth has come from
experiments in which active or inactive mutants of members of the
cascade or upstream signaling elements have been overexpressed in
transformed cells. This information can then be used as a basis to
investigate the role of the ERK/MAPK cascade in mitogenic signaling
from specific receptors in nontransformed, primary cultures as well as
the components of the pathway that link the receptors to the cascade.
Extracellular ATP acts as a mitogenic signal in primary cultures of
cerebral cortical astrocytes from newborn rats (Neary et al., 1994a,b).
Because ATP also stimulates ERK activity in these cells (Neary and Zhu,
1994; King et al., 1996), this suggests that ERK is involved in
ATP-induced mitogenesis. However, in addition to phosphorylating and
activating transcription factors involved in gene expression needed for
proliferation and differentiation, ERK has other targets, including
proteins in the cytoplasm, membrane, and cytoskeleton; therefore, ERK
may have other roles besides regulating cell growth (Seger and Krebs, 1995). For example, by phosphorylating myosin light-chain kinase, ERK
can regulate cell motility by a pathway independent of gene transcription (Klemke et al., 1997). Thus, the stimulation of ERK by
extracellular ATP does not provide sufficient evidence to conclude that
ERK mediates mitogenic signaling by ATP/P2Y receptors in astrocytes. To
investigate this question, we used PD 098059, an inhibitor of the ERK
activator MEK1 (Dudley et al., 1995). PD 098059 has been shown to block
ERK stimulation and to inhibit growth factor-induced proliferation in
Swiss 3T3 mouse fibroblasts and rat kidney cells at concentrations that
were not cytotoxic. PD 098059 is highly selective for MEK1, as
evidenced by its failure to inhibit 18 other serine/threonine protein
kinases in vitro and in vivo, including the ERK
homolog Jun N-terminal kinase (also known as stress-activated protein
kinase) (Alessi et al., 1995). If the ATP-evoked activation of ERK and
the ATP-induced mitogenic response are causally related, PD 098059 should block the ability of ATP to stimulate DNA synthesis. Indeed,
this was observed (Fig. 7B), thereby indicating the
importance of the ERK/MAPK cascade in mediating mitogenic signaling by
ATP receptors in astrocytes.
| |
FOOTNOTES |
Received Nov. 16, 1998; revised March 9, 1999; accepted March 15, 1999.
This work was supported by the Department of Veterans Affairs.
Correspondence should be addressed to Dr. J. T. Neary, Research
Service 151, Veterans Affairs Medical Center, 1201 NW 16th Street,
Miami, FL 33125.
| |
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ABSTRACT
INTRODUCTION
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