Endocrine Research Group, Department of Pharmacology & Therapeutics
and Department of Medicine, The University of Calgary Faculty of
Medicine, Calgary, Alberta, Canada T2N 4N1
Using a guinea pig gastric longitudinal smooth muscle preparation, we
have compared the contractile signaling pathways triggered by the
thrombin receptor-activating peptide, TFLLR-NH2 (TF) and by
epidermal growth factor-urogastrone (EGF). In addition to inhibitors of
tyrosine kinase [tyrphostin 47/AG213, genistein and the src-selective inhibitor CP118,556/PP1], cyclooxygenase (indomethacin, INDO) and
diacylglycerol lipase (U57, 908), we also used the signal pathway probe
inhibitors of mitogen-activated protein-kinase-kinase (MEK:PD98059),
phosphatidylinositol 3'-kinase [PI3K: Wortmannin (WM) and LY294002],
protein kinase C [PKC: GF109203X (GF)], and of the EGF-receptor
kinase (PD153035). We found that in addition to the inhibition of both
TF and EGF-stimulated contractions by the inhibitors of tyrosine
kinase, cyclooxygenase and diacylglycerol lipase, the actions of TF and
EGF were also attenuated by PD98059, WM/LY294002 and GF. However,
PD153035 blocked only EGF-triggered contractions. The contractile
actions of both TF and EGF were dependent on extracellular calcium. In
contrast, the contractile action of arachidonic acid, via a presumed
cyclooxygenase product that mediated the contractions caused by both TF
and EGF, was not blocked by any of the signal pathway probe inhibitors.
The contractile actions of both TF and EGF were accompanied by
increases in tissue phosphotyrosyl proteins and an increase in tissue
c-src kinase activity. We conclude that protease-activated receptor no.
1- (thrombin receptor) mediated contractions in the logitudial muscle,
like EGF receptor-activated responses, require the influx of
extracellular calcium and use parallel signal pathways upstream of the
cyclooxygenase step, involving MEK, PI3K, kinase C and possibly
cellular src. The TF-induced response did not involve trans-activation
of the EGF receptor kinase; but the converse (i.e.,
trans-activation of protease-activated receptor no. 1 (thrombin receptor) by the EGF receptor kinase) could not be ruled out.
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Introduction |
Although
EGF acting via its tyrosine kinase receptor is widely recognized for
its mitogenic and acid-inhibitory activity (Cohen, 1962
; Gregory,
1975), it is now appreciated that this peptide can also modulate the
contractility of a variety of smooth muscle preparations, including
those coming from vascular and stomach tissue (Berk et al.,
1985; Muramatsu et al., 1985, 1988; Hollenberg, 1994a, b).
Thrombin, best known for its role in the coagulation cascade, is now
also known to cause a variety of responses in target tissues ranging
from platelets to the vasculature. Thrombin acts on its target tissues
via a G-protein-coupled receptor (PAR1: Vu
et al., 1991; Rasmussen et al., 1991) and as with
EGF, exhibits potent mitogenic activity in a variety of cell systems.
Also as with EGF, thrombin can regulate gastric smooth muscle
contractility via a signaling pathway that depends both on
cyclooxygenase- and tyrosine kinase-mediated events (Hollenberg
1994a,b, 1996). Although not yet established, it is possible that the
contractile actions caused by PAR1 or EGF
receptor activation in gastric or vascular smooth muscle may play a
role in the settings of tissue injury or inflammation. The intriguing
mechanism whereby thrombin activates its G-protein-coupled receptor
involves the proteolytic unmasking of an N-terminal anchored
receptor-activating ligand (Vu et al., 1991; Coughlin
et al., 1992). Strikingly, short synthetic peptides, based
on the proteolytically revealed receptor-activating sequence, can on
their own activate the thrombin receptor, so as to mimic the actions of
thrombin in many tissues, including not only platelets (Vu et
al., 1991) but also vascular and gastric smooth muscle (Muramatsu
et al., 1992; Simonet et al., 1992; DeBlois
et al., 1992; Yang et al., 1992a).
Structure-activity studies of the receptor-activating peptides in work
by us (Hollenberg et al., 1997; Kawabata et al., 1997) and by others (Blackhart et al., 1996) have led to the
development of peptides that activate selectively either the thrombin
receptor (PAR1APs) or the closely related
receptor (PAR2) that is activated by trypsin, but
not thrombin (Nystedt et al., 1994, 1995). In our own work
(Hollenberg et al., 1997), the PAR1AP,
TF has been found to activate PAR1 selectively
compared with PAR2 both in intact tissue and in
isolated cell assays; and new data indicate that this peptide will not
activate the recently described thrombin receptor,
PAR3, which as with PAR1 is
activated specifically by thrombin but not by trypsin (Ishihara
et al., 1997).
In our initial work with PAR1APs, we noted as
outlined above, that in the gastric LM preparation obtained from either
rats or guinea pigs, there are parallels in the contractile actions of
the growth factor EGF and PAR1-activating
peptides, in that both contractile responses can be blocked by the
cyclooxygenase inhibitor, indomethacin and the tyrosine kinase
inhibitors, genistein and tyrphostin (Hollenberg et al.,
1992). After the completion of that work, a number of issues have come
to light that have prompted us to examine in more depth, the activation
of the LM PAR1 in comparison with the activation
of the LM EGF receptor; and to compare more fully the growth factor
signaling pathways that are involved in the contractile actions of the
EGF and PAR1 receptor systems in gastric LM
tissue. First, it is now clear that the PAR1AP,
SFLLR-NH2 used in our previous work with gastric LM tissue can activate both PAR1 and
PAR2 (Blackhart et al., 1996; Hollenberg et al., 1997); these two receptors are both
present in gastric LM tissue (Al-Ani et al., 1995). Second,
it is now recognized that some actions of G-protein-coupled receptor
agonists, including thrombin, may possibly result from transactivation
of the EGF receptor (Daub, et al., 1996)., and we wished to
rule out this mechanism for the contractile effect of
PAR1 activation in smooth muscle. It has been our
working hypothesis, that because EGF and thrombin can both activate
similar "growth factor" responses in fibroblast mitogenesis assays,
the two receptor systems (i.e., PAR1
and EGF receptor kinase) may also activate common "growth factor-"related signaling pathways to cause a rapid contractile response in smooth muscle systems. In view of the two concerns outlined
in the above paragraph and in view of our working hypothesis that EGF
and thrombin may activate common signaling pathways to cause a rapid
contractile response in smooth muscle, we have used the
PAR1-selective agonist, TF, to activate
PAR1 in guinea pig gastric LM tissue for
comparison with the activation of the EGF receptor. The aim of our work
was to study the contractile response of the guinea pig LM preparation
using several tyrosine kinase inhibitors, including the one targeted to
src-family kinases (CP 118, 556 or PP1: Hanke et al., 1996),
along with other signal pathway probes [PD153035, a high potency
specific inhibitor of the EGF receptor kinase (Fry et al.,
1994); PD98059, an inhibitor of mitogen-activated protein kinase kinase
or MEK (Dudley et al., 1995); Wortmannin (WM) and LY294002
(inhibitors of PI3K) (Ui et al., 1995); the kinase C
inhibitor GF109203X (Toullec et al., 1991) and the
diacylglycerol lipase inhibitor, U57, 908 (Sutherland and Amin, 1982;
Yang et al., 1991)]. These enzyme inhibitor reagents were
used to compare in parallel the contractile activation pathways for
PAR1 and the EGF receptor. Further, in the
context of contractile response both PAR1 and EGF
receptor-induced contractile responses, we evaluated increases in
tissue phosphotyrosyl proteins and in the activity of the cellular
nonreceptor tyrosine kinase, c-src. One major goal was to establish in
further depth the signal pathways activated by
PAR1 in an intact smooth muscle system, and to
compare these pathways with the signal pathways activated by EGF.
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Methods |
Tissue preparations for bioassay.
The guinea pig gastric LM
and CM preparations were prepared as described previously (Muramatsu
et al., 1988; Yang et al., 1993) from male albino
Hartley strain animals weighing about 350 g. Animals were cared
for in accordance with the Canadian Council on Animal Care and were
killed by rapid cervical dislocation, followed by exsanguination via
the common carotid arteries and excision of the stomach tissue. The
stomach was stripped carefully of overlying muscosa under a dissecting
microscope after which the CM and LM preparations were prepared by
cutting along (CM tissue) or at right angles (LM tissue) to the visible
circular muscle bundles. This procedure permits the measurements of the contraction of either the LM or CM elements in the same tissue sample
(Muramatsu et al., 1988). The width and length of the
preparations were approximately 3 × 10 mm, respectively. The
tissue preparations were mounted vertically in a plastic cuvette
thermostated at 37°C, containing 4 ml of gassed (95%
O2/5% CO2) Krebs-Henseleit
solution pH 7.4 of the following composition (millimolar): NaCl, 118;
KCl, 4.7; CaCl2 2.5; MgCl2,
1.2; NaHCO3, 25;
KH2PO4, 1.2 and glucose, 10; in distilled deionized water. A tension of 1 g was applied and
the tissue was allowed to equilibrate at 37°C for about 1 hr.
Contractile responses were recorded isometrically through force-displacement transducers (either Statham UTC2 or Grass). Routinely, the integrity of each preparation was assessed by monitoring the contractile responses to 50 mM KCl and 1 µM Cch. For
concentration-response curves, the contractile actions of increasing
concentrations of TFLLR-NH2 in the LM preparation
(measured at the peak of the contractile response, e.g.,
fig. 2A) were expressed as a percentage (% KCl) of the contraction
caused by 50 mM KCl (1.2 ± 0.3 g for n = 25) in the same tissue preparation. The assay of peptide activity was done
in the presence of amastatin (10 µM) to inhibit aminopeptidase activity.
Routinely, tissues were exposed to contractile agonists (EGF, TF, etc.)
at 30-min intervals, followed by a tissue wash shortly after the
plateau of the contractile response. When present, the signal pathway
probes were added to the organ bath 20 min before the addition of
contractile agonists (17 nM EGF; 1 µM TF; 10 µM AA). For the
construction of concentration-inhibition curves for the signal pathway
inhibitor probes, contractile responses were expressed as a percentage
(% control) of the peak contractile response observed for each tissue
at a fixed concentration of contractile agonist (EGF, TF or AA, as
above), before treatment with the signal pathway probe of interest.
Drugs were added to the organ bath directly, and concentrations were
calculated accordingly.
Western blot analysis and assay of Src-tyrosine kinase
activity.
LM tissue strips to be used for Western blot analysis
and for the assay of Src-tyrosine kinase activity were prepared and treated with agonists (17 nM EGF or 1 µM TF) exactly as for the LM
bioassay and were removed from the organ bath for processing at a time
corresponding to the peak of tissue contraction, as detailed in
previous work from this laboratory (Yang et al., 1992b, 1993). For Western blot analysis, tissue was quick-frozen on solid CO2 and stored at -70°C for further analysis.
Tissue was quick-thawed and homogenized in a 50 mM Tris HCl buffer, pH
7.4, containing protease inhibitors (0.2 mg/ml benzamidine, 0.1 µg/ml
soybean trypsin inhibitor, 10 µg/ml leupeptin and 0.3 mM PMSF) and
supplemented with 1 mM EDTA, 2 mM MgCl2 and 0.2 mM Na2VO4. Debris was
removed from the homogenate, by low speed centrifugation (3000 RPM × 30 min at 4°C; Beckman TI65 rotor). Equal aliquots of protein
extract (corrected for buffer blank: Bradford Reagent (Bio-Rad,
Missisauga, Ontario, Canada) were combined with an equal volume of 2x
concentrated immunoprecipitation buffer pH 7.4, that at 1x
concentration contained 50 mM Tris HCl, 1 mM EGTA, 0.2 mM
NO2VO4, 0.2 mM PMSF, 150 mM NaCl, 0.5% v/v NP-40 and 1% v/v triton X-100. For each tissue sample,
equal amounts of protein extract were subjected to immunobead purification using monoclonal antiphosphotyrosine antibody (6D9) prepared according to Glenney et al. (1988) and coupled to
Sepharose beads. The final washed bead pellet was solubilized in
boiling electrophoresis sample buffer (Laemmli, 1971) in preparation
for polyacrylamide gel electrophoresis (70 × 100 × 1.5 mm,
8% gel) and transfer to nitrocellulose (0.45 µm; Bio-Rad, Richmond,
CA) for Western blot detection of protein. The same monoclonal
antiphosphotyrosine antibody (6D9) coupled directly to horseradish
peroxidase was used for visualization of membrane-bound proteins using
enhanced luminescence detection (Amersham, Oakville, Ontario, Canada). Control experiments demonstrated that the phosphotyrosyl protein signal
could be quenched by pretreatment of the antibody with a phosphotyrosyl
hapten (either 12.5 mM phenylphosphate or 5 mM phosphotyrosine). Tissue
to be analysed for Src-kinase activity was extracted with 0.5%
NP-40/1% Triton x-100 as described above for immunoprecipitation. For
each tissue sample, equal amounts of protein in the clarified
detergent-containing tissue extract were supplemented with monoclonal
anti-Src antibody 327 (Oncogene Sciences, Manhasset, NY) followed 1.5 hr thereafter by the addition of rabbit anti mouse immunoglobin (5 µg/ml, 1.5 hr at 4°C) and assayed for Src-kinase activity, using
the cdc2 (6-20) peptide as a substrate
(KVEKIGEGTYGVVYK-NH2) essentially as described previously (Cheng et al., 1992). Before the assay, the
immune complex was washed 3x with the immunoprecipitation buffer
(above) and once with the kinase assay buffer (below). Assays were
performed at 30°C over a 20-min interval in a 50 µl final reaction
volume, using a kinase assay buffer, pH 7.0, comprising 50 mM Tris-HCl, 50 mM MgCl2, 10 mM MnCl2,
50 µM Na3VO4, 7 mg/ml
p-nitrophenylphosphate (2 mM) and 100 µM 
32P-ATP (range of specific activity, 300-1000 CPM/pmol). The cdc2 peptide substrate was at a concentration of 300 µM. The reaction was started by the addition of 32P-ATP and terminated 20 min thereafter by the
addition of 25 µl of 50% (v/v in H2O) acetic
acid. The phosphorylated substrate was recovered by spotting 60-µl
aliquots of the acidified reaction mixture on Whatman P81
phosphocellulose paper. cdc2-peptide-free reaction mixtures were used
as a "background" blank. The washed [3x with 0.5% (v/v in
H2O)
H3PO4] filter papers were
acetone-extracted and air-dried before the measurement of incorporated
radioactivity by scintillation counting. Under these conditions, it has
been established (Cheng et al., 1992) that phosphate
incorporation is linear over at least 30 min and that less than 3% of
the substrate is consumed in the reaction. Routinely, the enzyme
activity was expressed as cpm
32PO4 incorporated per
sample over a 20-min interval, corrected for the
non-substrate-containing "blank."
Reagents.
Human EGF was from Upstate Biotechnology Inc.
(Lake Placid, NY); PD98059 and PD153035 were obtained from Parke Davis
(Ann Arbor, MI), with the kind assistance of Drs. A. Saltiel and D. Fry. U57, 908 was a generous gift to Dr. D. L. Severson,
originally from Dr. D. Morton (The Upjohn Co., Kalamazoo, MI). The
following reagents were obtained from Sigma (St. Louis, MO):
nifedipine, indomethacin and wortmannin. Calbiochem (La Jolla, CA)
provided arachidonic acid, tyrphostin 47/AG213 and GF109203X, whereas
the Src-selective kinase inhibitor, CP118, 556/PP1, was obtained
through the courtesy of Dr. Hanke, Pfizer Central Research. Peptides
(TFLLR-NH2 and KVEKIGEGTYGVVYK) were synthesized
by solid phase methodology with the assistance of Dr. D. McMaster of
the Peptide Synthesis Facility at the University of Calgary, Faculty of
Medicine (Calgary, AB, Canada). The concentration, purity and
composition of peptide stock solutions (>95% purity) were determined
by high-performance liquid chromatography, mass spectrometry and
quantitative amino acid analysis.
Statistical analysis of data.
Values (averages ± S.E.M.) expressing the contractile response (% KCl) relative to that
of 50 mM KCl; or the degree of inhibition (% control) of contraction
by a variety of agents, relative to the contractile responses observed
in the absence of inhibitors were obtained from experiments done with 3 to 15 independently prepared tissue strips usually coming from two or
more separate animals. The average values ± S.E.M., recorded in
the tables and in the figures (error bars shown), comparing responses
in inhibitor-treated vs. untreated tissues were assessed for
statistical significance, where appropriate, using either paired or
group Student's t tests.
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Results |
Sensitivity of the guinea pig LM and CM preparations to
TFLLR-NH2.
Our previous work had
established the PAR1 (vs.
PAR2) selectivity of the
PAR1AP, TFLLR-NH2, in both
tissue and cell-based assays (Hollenberg et al., 1997).
Nonetheless, we had yet to study the sensitivity of the guinea pig
gastric smooth muscle preparations to TFLLR-NH2.
Therefore, we determined the concentration-response curve shown in
figure 1, wherein an
EC50 of about 0.9 µM was observed. As with EGF,
and in keeping with our observations with
SFLLR-NH2 (Hollenberg et al., 1992),
TFLLR-NH2 caused a transient contractile response
that rose to a maximum within 5 min, and then declined toward baseline
tension over a further 10- to 15-min time period (insert, fig. 1).
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Fig. 1.
Concentration-effect curve for the contractile
action of TFLLR-NH2 in LM tissue. The contractile responses
of LM tissue strips to increasing concentrations of
TFLLR-NH2 were measured and expressed as a percentage (% KCl) of the contraction caused in each tissue by 50 mM KCl. The inset
shows a representative transient contractile response to 1 µM
TFLLR-NH2 (TF-NH2,  ). The scale for time and
tension is shown to the right of the tracing; W (arrow) = tissue wash.
Values represent the mean ± S.E.M. (error bars) for measurements
done with four to six individual tissues taken from two to four
different animals.
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Because in previous work (Muramatsu et al., 1988; Yang
et al., 1993) we had observed an agonist-mediated
contraction of the indomethacin- (3 µM) treated circular muscle
preparation, we also evaluated the action of
TFLLR-NH2 on the indomethacin-treated CM tissue.
Concentrations of the peptide as high as 20 µM failed to elicit a
contractile response (not shown). For that reason, it was not possible
to compare the distinct EGF signaling pathway in the CM preparation (as
opposed to the LM) with that of TFLLR-NH2 in the
CM preparation; and thus, all of the continuing studies to compare the
signal pathways for TFLLR-NH2 and EGF in the
guinea pig gastric tissue were conducted with the LM preparation. In agreement with our previous observations with the action of other agonists in the LM preparation (Muramatsu et al., 1988), the
contractile actions of TFLLR-NH2 were not
affected by the following pharmacological antagonists (all at 1 µM):
tetrodotoxin, atropine, prazosin and yohimbine.
Effects of inhibitors of cyclooxygenase, tyrosine kinase and
diacylglycerol-lipase.
In keeping with our previous observations
with the PAR1/PAR2
nonselective agonist, SFLLR-NH2 (Hollenberg
et al., 1992) in guinea pig and rat gastric tissue, the
contractile action of the PAR1-selective agonist,
TFLLR-NH2 was blocked by the cyclooxygenase inhibitor, indomethacin, but not by either the epoxygenase inhibitor, ketoconazole (5 µM) or the lipoxygenase inhibitor,
nordihydroguairetic acid (30 µM) (fig.
2A and data not shown). The tyrosine
kinase inhibitors, tyrphostin 47 (AG213) and genistein, both blocked the contractile response to TFLLR NH2. As we had
previously observed for EGF-stimulated contractions (fig. 2E and Yang
et al., 1992b), maximal inhibition for
TFLLR-NH2-induced contractions was observe at 7.5 µM genistein and at 20 µM tyrphostin 47 (AG213); the inhibition caused by 7.5 µM genistein (100%) was the same as that caused by 20 µM tyrphostin 47 (AG213) (fig. 2D). The diacylglycerol lipase inhibitor, U57, 908, also blocked the contractile response (fig. 3). In
contrast, the phospholipase A2 inhibitor,
mepracrine (3 µM) had no effect on the contractile response (not
shown). At the concentrations of indomethacin, tyrphostin 47/AG213 and
U57, 908 that were used, we had previously shown that these inhibitors were able to block the contractile actions of EGF (figs. 2 and 3) without affecting contractions caused
by either bradykinin or carbachol (Yang et al., 1991,
1992b). In addition to the tyrosine kinase inhibitors, tyrphostin
47/AG213 and genistein, the Src-selective tyrosine kinase inhibitor,
CP118, 556/PP1 (Hanke et al., 1996) was able to block
contractions caused by both EGF and TFLLR-NH2 with comparable IC50s (50 to 80 nM) (fig.
4).
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Fig. 2.
Comparative effects of indomethacin and
tyrphostin-47 on the contractile actions of TFLLR-NH2, EGF
and arachidonic acid in the LM preparation. After monitoring a control
contractile response to TFLLR-NH2 (TF-NH2,
1µM, A and D), EGF (17 nM, B and E) and arachidonic acid (AA, 10 µM, C and F), tissues were washed (W, arrow) and pretreated for 20 min with either indomethacin (IND, 3 µM, A to C) or tyrphostin-47
(TP47, 20 µM, D to F) and the tissues were then rechallenged with the
same agonists. The tracings are representative of results obtained with
four to six tissue strips derived from three or more animals.
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Fig. 3.
Effect of the diacylglycerol lipase inhibitor, U57,
908 on LM contractions caused by TFLLR-NH2 and EGF. After
monitoring a control contraction in response to either
TFLLR-NH2 (TF, 1 µM) or EGF (17 nM), tissues were washed
and were incubated for 20 min with 20 µM U57, 908 (solid bars). The
preparations were then rechallenged with the same agonists in the
continued presence of U57, 908. The contractile response in the
presence of the inhibitor (solid bar) was expressed as a percentage (% control) of the contractile response observed in the absence of
inhibitor. The solid bar shows the average response (% control) ± S.E.M. (error bars) for data obtained with seven different tissues
strips. **P < .001 compared with control.
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Fig. 4.
Effect of the Src-selective tyrosine kinase
inhibitor, PP1, on contractions caused by TFLLR-NH2, EGF
and arachidonic acid in the LM preparation. After monitoring control
contractile response to TFLLR-NH2 (TF, 1 µM: ), EGF
(17 nM,  ) or arachidonic acid (AA, 10 µM:  ), tissues were
washed and preincubated for 20 min with increasing concentrations of
PP1 (x-axis) before a rechallenge of each tissue with the same agonist
in the continued presence of PP1. The contractile responses in the
presence of PP1 were expressed as a percentage (% control) of the
response observed in the absence of inhibitor. Data points represent
means ± S.E.M. (bars) for measurements with four to six
individual tissue strips for each concentration of PP1.
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Role of extracellular calcium.
We confirmed in the present
study that, as previously published, EGF did not cause a contractile
response in the absence of extracellular calcium (data not shown and
Laniyonu et al., 1994). Similarly, a contraction in response
to TFLLR-NH2 was not observed in the absence of
extracellular calcium (upper tracing, fig.
5); replenishing the buffer with
extracellular calcium, in the continued presence of the
receptor-activating peptide, resulted in a contractile response (upper
tracing, fig. 5). For reasons we were unable to determine, the
readdition of extracellular calcium to a tissue preactivated by
TFLLR-NH2 without Ca++
resulted in a tonic, rather than a transient contractile response, as
observed when TFLLR-NH2 was added to the tissue
in the concurrent presence of 2.5 mM Ca++ (see
insert, fig. 1). In accord with this result, the calcium channel
antagonist, nifedipine (1 µM) essentially abolished the contractile
response of the LM preparation to TFLLR-NH2
(lower tracing, fig. 5). As expected, the contractile response to 50 mM
KCl was also blocked by nifedipine.
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Fig. 5.
Dependence of the contractile response of the LM
preparation to TFLLR-NH2 on extracellular calcium. Upper,
The preparation was first exposed to TFLLR-NH2 (TF, 1 µM:
) followed by washing (W, arrow) and resuspension in a calcium-free
Krebs-Henseleit buffer containing 0.2 mM EGTA (Ca++-free).
Twenty minutes thereafter, the tissue was again challenged in
calcium-free buffer with TFLLR-NH2 (); the replenishment
of the buffer with 2.5 mM CaCl2 (+) in the continued
presence of TFLLR-NH2 resulted in a contractile response.
(lower): After monitoring a control response to TFLLR-NH2,
the tissue was washed and preincubated for 20 min with the
voltage-dependent calcium channel blocker, nifedipine (NIF, 1 µM:
 ). TFLLR-NH2 was then added to the organ bath in the
continued presence of nifedipine. The tracings are representative of
experiments done with three or more tissue strips taken from at least
two different animals.
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Effects of inhibitors of PKC, PI3K and MEK.
We had not
previously, in the guinea pig LM preparation, assessed potential roles
for PKC, phosphatidylinositol 3' kinase and MAP-kinase-kinase in the
contractile actions for the
PAR1/PAR2-activating peptides. Although we had recently reported that inhibitors of these
three enzymes could block the contractile action of EGF in the guinea
pig LM tissue (Zheng and Hollenberg, 1997; Zheng et al.,
1997), we believed it necessary to reevaluate in more detail, with
comparable tissue samples from the same series of animals, the effects
of the inhibitors on the actions of TFLLR-NH2 and
EGF. The PKC inhibitor, GF109203X, at 1 µM was found to block completely contractions elicited in the LM preparation by the PKC
activator, phorbol dibutyrate (not shown). This same concentration of
GF109203X was also able to inhibit (90 ± 5%, mean ± S.E.M. for n = 5) the EGF-mediated contractile response; but
in contrast, GF109203X was not able to block more than 50% of the
contractile response caused by TFLLR-NH2
(inhibition: 50 ± 5%, mean ± S.E.M. for n = 6) (fig. 6). Similarly, the PI3 kinase
inhibitors wortmannin (0.1 µM) and LY294002 (2.5 µM) were able to
block the contractile response to EGF almost completely (90 ± 5%
inhibition, mean ± S.E.M. for n = 5), but were
only partially effective (58 ± 5% inhibition: mean ± S.E.M. for n = 6) in blocking the contractile response
caused by TFLLR-NH2 (fig.
7). These concentrations of Wortmannin
and LY294002 were at the respective plateaus of their concentration-inhibition curves (not shown). The
IC50 for Wortmannin was approximately 70 nM, in
keeping with the potency of this reagent to inhibit PI3 kinase. When
added together, the PKC inhibitor, GF109203X (1 µM) and Wortmannin
(0.1 µM) were able to block the TFLLR-NH2-induced contraction completely (fig.
6). In contrast, the contractile responses to 1 µM carbachol or 50 mM
KCl were unaffected by either 0.1 µM Wortmannin or 1 µM GF109203X
(data not shown). The selective MEK inhibitor, PD98059 was able to
block completely contractions caused both by EGF
(IC50, approx. 0.1 µM) and by
TFLLR-NH2 (IC50, approx.
0.2 µM) (fig. 8). The MEK inhibitor had
no effect on the contractile response elicited by 1 µM carbachol (not
shown).
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Fig. 6.
Effects of the protein kinase C inhibitor GF109203X
on the contractile responses of LM tissue. LM tissue strips were first
exposed to EGF (17 nM), TFLLR-NH2 (TF, 1 µM) and
arachidonic acid (AA, 10 µM). The control responses (open bars) were
recorded, followed by a tissue wash and incubation of each tissue with
1 µM GF109203X (GF) for 20 min. The tissue responses to the same
contractile agonists were subsequently recorded in the continued
presence of 1 µM GF (solid bar); these responses were expressed as
the percentage of the previous contraction observed in the absence of
inhibitor (Y-axis). For TF-stimulated contractions, the combined
effects of 1 µM GF plus .1 µM wortmannin (WM/bar) were also
monitored (hatched bar). Data represent the mean ± S.E.M. (error
bars) for measurements done with seven individual tissue strips for
each experimental group. Student's t test, **P < .01, compared with control responses.
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Fig. 7.
Effects of inhibitors of PI3-kinase on
agonist-induced contractions in the LM preparation. After monitoring
the control contractile responses (empty bars) in LM tissues to EGF (17 nM), TFLLR-NH2 (TF, 1 µM) and arachidonic acid (AA, 10 µM) (shown on x-axis), followed by a tissue wash, the tissues were
preincubated for 20 min with the PI3-kinase inhibitors, either
wortmannin (WM, solid bar, 0.1 µM) or LY294002 (LY, hatched bar, 2.5 µM). The contractile responses to various agonists obtained in the
presence of the PI3-kinase inhibitors were expressed as the percentage
of the control responses (y-axis). Data represent the mean ± S.E.M. (error bars) for measurements done with seven individual tissue
strips for each experimental group. **P < .01, compared with
control responses.
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Fig. 8.
Concentration-effect curves for the inhibition of
contraction by the MEK inhibitor, PD98059. The gastric longitudinal
muscle (LM) preparations were exposed to arachidonic acid (AA 10 µM:
), EGF (17 nM: ) or TFLLR-NH2 (TF, 1 µM: ) to
obtain the control responses, followed by a tissue wash. The tissues
were then preincubated with various concentrations of the MEK
inhibitor, PD98059 (x-axis), for 20 min, after which the responses to
the same concentrations of AA, EGF and TFLLR-NH2 were
recorded and expressed as the percentage of the corresponding control
responses (y-axis). Data represent the mean ± S.E.M. (error bars)
for measurements done with nine individual tissue strips for each
concentration point.
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Effect of the EGF receptor kinase inhibitor, PD153035.
Because
previous work had shown that the EGF receptor could be potentially
transactivated by thrombin in cultured Rat-1 fibroblasts, we wished to
demonstrate that the contractile action of
TFLLR-NH2 in the LM preparation was not due to
the concurrent activation of the EGF receptor. To deal with this
possibility, we used the potent and selective EGF receptor kinase
inhibitor, PD153035, that is not believed to affect other kinases, such
as kinase C or src-kinase (Fry et al., 1994). As shown in
figure 9, the receptor kinase inhibitor
was able to abolish the contractile action of EGF in the LM
preparation, with an IC50 of about 50 nM, without affecting the contractile action of TFLLR-NH2 at
inhibitor concentrations as high as 1 µM. Unfortunately, a selective
inhibitor of PAR1 activation is not yet
available, and it was not possible to assess whether the reciprocal
mechanism (i.e., trans-activation of
PAR1 by the EGF receptor kinase) might occur.
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Fig. 9.
Concentration-dependent effect of the EGF receptor
kinase inhibitor, PD153035, on the contractile responses caused by EGF
and TFLLR-NH2. The responses of lognitudinal muscle (LM)
preparations to EGF (17 nM: ) or TFLLR-NH2 (TF, 1 µM:
) were first obtained and recorded as the control. Tissues were then
washed and preincubated with various concentrations of PD153035
(x-axis), followed by exposure to the same concentrations of EGF and
TFLLR-NH2. The contractile responses obtained in the
presence of PD153035 were expressed as the percentage of the control
response observed in the absence of this inhibitor (y-axis). Data
represent the mean ± S.E.M. (error bars) for measurements done
with eight individual tissue strips for each concentration point.
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Effects of inhibitors on the contractile effect of exogenously
added arachidonic acid.
For both EGF and
TFLLR-NH2, the inhibitory actions of indomethacin
and U57, 908 indicated that the LM contractile response itself was due
to a presumed cyclooxygenase metabolite of AA, most likely acting via a
G-protein-coupled receptor distinct from PAR1.
Thus, to distinguish between the effects of the various inhibitors on
the PAR1 signaling pathway from possible effects on the receptor(s) activated by the arachidonic acid metabolite(s), it
was necessary to evaluate the effects of the various inhibitors on the
contractile action of AA itself; we presumed that AA would be converted
to one or more contractile metabolites by the LM tissue. Preliminary
work showed that 10 µM of arachidonic acid added to the organ bath
yielded a contractile response equivalent to the response caused by
either 1 µM TFLLR-NH2 or 17 nM EGF (fig. 2).
Thus, further work was done using this concentration of arachidonate. In keeping with our working hypothesis that a cyclooxygenase product of
arachidonate was responsible for the observed contractile effect caused
by EGF and TFLLR-NH2, 3 µM indomethacin
completely blocked the contractile action of added arachidonate (fig.
2C). The contractile response to arachidonate also required the
presence of extracellular calcium and was attenuated by the calcium
channel blocker, nifedipine (not shown; and table
1). However, unlike the actions of EGF and TFLLR-NH2, the contractile action of
arachidonate was not affected by the other inhibitors we tested (see
table 1), including the tyrosine kinase inhibitors tyrphostin 47/AG213
and CP118, 556/PP1 (figs. 2 and 4), the MEK inhibitor PD98059 (fig. 8),
the PI3-kinase inhibitors Wortmannin and LY294002 (fig. 7) and the protein kinase C inhibitor, GF109203X (fig. 6). In this manner, it was
possible to distinguish clearly between the common signal pathways
activated by PAR1 and the EGF receptor kinase,
and the contractile signal pathway activated by the metabolite(s) of
AA. Table 1 summarizes the effects of all of the inhibitors we tested on the actions of EGF, TFLLR-NH2 and
arachidonate.
Phosphotyrosyl proteins and Src-kinase activity.
Because the
Src-selective inhibitor, CP118, 556/PP1 blocked the contractile action
of EGF and TFLLR-NH2, we wished to assess the
presence of phosphotyrosyl proteins in the LM tissue that had been
contracted by either EGF or TFLLR-NH2; and we
wished to determine if Src-kinase activity was indeed elevated during the contractile process. As shown in table
2 and figure 10, EGF and
TFLLR-NH2 both caused increases in Src-kinase
activity, as determined after immunoprecipitation using the
Src-targeted cdc2 peptide as a substrate; and both contractile agonists
caused an increase in phosphotyrosyl proteins that were harvested by
antiphosphotyrosine immunobeads, as detected by Western blotting with
horseradish peroxidase-coupled monoclonal antiphosphotyrosine antibody.
Nonetheless, the degree of increase of phosphotyrosyl proteins detected
after agonist treatment (A to F in fig.
10) appeared to differ for EGF and
TFLLR-NH2. For instance, desensitometry of the
phosphotyrosyl protein bands C and E (fig. 10) showed that there were
comparable increases (about 1.3-fold, relative to control) caused by
either TF or EGF; but, for constituents B and D, EGF caused a more
pronounced increase in tyrosine phosphorylation (about 2.5-fold for B;
2.1-fold for D) compared with TF (about 1.5-fold for B; 1.3-fold fold
D). These possible differences in the tyrosine phosphorylation
triggered by the two agonists will require further study using
antibodies directed against specific signal pathway components such as
the 85-kDa regulatory subunit of PI-3K (possibly, fig. 10C) that can become tyrosine phosphorylated in the course of EGF action.
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Fig. 10.
Increase in phosphotyrosyl protein content
stimulated by EGF and TFLLR-NH2. Tissues (LM preparation)
were mounted in the organ bath and were equilibrated as for a bioassay.
In triplicate, tissue strips were either untreated, or were exposed to
EGF (17 nM) or TFLLR-NH2 (1 µM). After observing a
reproducible contraction to either EGF or TFLLR-NH2,
followed by washing and reequilibration, the preparations were again
exposed to each agonist and were harvested at the point when tension
was about 80% of the plateau level (at about 2 min after adding
agonist). Control tissues were harvested after the same
equilibration/washing procedures, but without the addition of agonists.
The triplicate tissues were pooled, rapidly frozen on solid
CO2 and processed for Western blot analysis and
chemiluminescence detection of phosphotyrosyl proteins, as outlined in
"Methods." Protein bands A to F (dots on right) were found to
exhibit an increased luminescence signal upon treatment with either EGF
(E) or TFLLR-NH2 (T) compared with control tissues (C).
Increases of luminescence over control bands were estimated by
quantitative densitometry, as recorded in the text for bands B to E. The position of the molecular weight markers (kDa) are shown on the
left; migration was toward the anode (arrow).
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Discussion |
The main finding of our study was that there is a remarkable
parallel between the signaling pathways activated by
PAR1 and by the EGF receptor kinase to cause a
contractile response in the guinea pig LM tissue. These parallels would
appear to be upstream of the steps (phospholipase activation and
diacylglycerol lipase action) leading to the formation of the
contractile AA metabolite. Based on our own recent data (Hollenberg
et al., 1997) and on work by others (Blackhart et
al., 1996; Ishihara et al., 1997), we are confident
that our results, using the receptor-activating peptide
TFLLR-NH2, reflect the selective activation of
PAR1 and not either PAR2 or
PAR3. The parallels between
PAR1 and EGF receptor kinase signaling pathways
included the activation of Src-tyrosine kinase activity and a
sensitivity of the tissue response toward inhibitors of PI3-kinase and
MEK. In contrast, the contractile action of the G protein-coupled
agonist, carbachol and of the (presumably) G-protein-coupled
cyclooxygenase product of arachidonic acid were unaffected by the
"growth factor" signal pathway probes that were used
(e.g., the Src-kinase inhibitors, CP118, 556/PP1; the PI3
kinase inhibitor wortmannin; and the MEK inhibitor, PD98059) (summarized in table 1). Further, the lack of effect of the potent EGF
receptor-kinase inhibitor, PD153035, to block the contractile action of
TFLLR-NH2, showed that PAR1
stimulation was not due to transactivation by the EGF-receptor tyrosine
kinase, as appears to be the case in cultured rat-1 fibroblasts (Daub
et al., 1996). Unfortunately, it was not possible to rule
out the converse possibility, that activation of the EGF receptor
kinase might have trans-activated PAR1. It can be
noted that for the contractile responses elicited by EGF and
TFLLR-NH2, there may be an unusual "double"
role for diacylglycerol, acting both "conventionally" as an
activator of kinase C (contractions attenuated by the kinase C
inhibitor GF109203X) and "unconventionally" as a substrate for
diacylglycerol lipase (contractions blocked by U57, 908). It is quite
likely that such a "metabolic" role for diacylglycerol, in addition
to its kinase C-activating role, may occur in the course of the action
of a number of agonists, as we have previously documented for
angiotensin-II (Yang et al., 1993). In the context of our
results showing that U57,908 (formerly known as RHC80267) blocked the
contractile action of TF, it is important to note that this compound
can also inhibit the effects of thrombin on guinea pig platelets (Amin
et al., 1986). To date, we have not been able to determine
whether the diacylglycerol is produced directly via the activation of a
phospholipase C isoform; or alternatively via the combined activation
of phospholipase D followed by phosphatidate phosphohydrolase.
Despite the many parallels between the actions of
TFLLR-NH2 and EGF, there were some minor but
significant differences in terms of the sensitivity of the contractile
responses to the various inhibitors (table 1). For instance, although
the contractile response to EGF was essentially abolished by the kinase
C inhibitor, GF109203X and by the PI3-kinase inhibitors, Wortmannin and
LY294002, the response to TFLLR-NH2 was not
completely blocked by these reagents. Yet, when added together, a
kinase C inhibitor and a PI3 kinase inhibitor abolished the contractile
response to PAR1 activation (fig. 6 and table 1).
Thus, in the guinea pig LM tissue, PKC would appear to play a major
role in the contractile action of EGF. It is possible that EGF acts
first via an upstream activation by PI3-kinase (Toker and Cantley,
1997; see also discussion below), followed sequentially by a kinase
C-mediated activation of the MEK/MAP kinase pathway (Ueda et
al., 1996). However, the activation pathway triggered by
TFLLR-NH2 would appear to involve both a PKC-dependent and a PKC-independent pathway that involves
the activation of both PI3-kinase and MEK in the course of the
contractile event. Previously, the activation of the MAP kinase pathway
via both a protein kinase C-dependent and independent pathway possibly involving tyrosine phosphorylation has been observed for the action of
thyrotropin-releasing hormone (Ohmichi et al., 1994). It is admittedly difficult, in the context of intact tissue studies (as
opposed to studies with cultured cell systems), to place PKC activation
as being unequivocally upstream or downstream of the activation of
either the nonreceptor tyrosine kinase or Ras (both of which we believe
are involved in the TFLLR-NH2-mediated the contractile response). One possibility that must be considered (Toker
and Cantley, 1997) is that phosphoinositides resulting from PI3-kinase
action [e.g., Ptd Ins (3, 4)P2 and
Ptd Ins (3, 4, 5)P3] could in turn activate PKC
isoforms in the LM tissue, placing PI3-kinase upstream of PKC in the
contractile process. Further studies will be required to resolve these
issues.
The analysis of the signal transduction pathways triggered by EGF and
TFLLR-NH2 to cause a contractile response is
challenging, since both of these agonists act via a "cascade"
process, wherein it is the indomethacin-sensitive cyclooxygenase
product of (presumably) arachidonic acid that ultimately drives the
contraction. Thus, in our study reported here, one must consider two
tiers of signal pathway activation: 1) the signal process triggered by
PAR1 and EGF receptor systems leading to the
activation of a phospholipase, that yields diacylglycerol and 2) the
signal process activated by the (presumed) prostanoid agonist via its
own G protein-coupled mechanisms to cause contraction. To sort out
these two tiers of signaling it was essential to examine the effects of
the various signal pathway probes on the contractile action of added
arachidonate itself. We fully realized the possibility that the
exogenous addition of arachidonate to the tissue might yield
contractile agonists in addition to the one(s) liberated in the course
of EGF and TFLLR-NH2 action. Despite these
reservations, an analysis of the data summarized in table 1 can permit
some conclusions to be made. First, the contractile response to 10 µM
AA was completely blocked by indomethacin. Contractions caused by 10 µM AA were equivalent in magnitude to those caused by TF and EGF.
Thus, we believe secure in our hypothesis that it is a cyclooxygenase
product that is responsible for the PAR1-driven
contractile response, and not an epoxygenase product, as we have
previously documented for the action of angiotensin-II in gastric CM
tissue (Yang et al., 1993). Second, because none of the
"growth factor" signal pathway probes we used attenuated the
response to added arachidonate (e.g., CP118,556/PP1,
GF109203X, wortmannin/LY294002, or PD98059), whereas all of these
compounds affected the contractile actions of both EGF and
TFLLR-NH2, we conclude that for both
TFLLR-NH2 and EGF the tyrosine kinase/PI3 kinase/kinase C/MEK signal pathways are upstream of the process of
activation of a phospholipase C or D isoform that yields diacylglycerol as a substrate for the ensuing production of the arachidonate metabolite. A further concern that the results resolve is the possibility that one or more of the signal pathway inhibitors might
have, as with indomethacin, blocked the action cyclooxygenase to yield
the contractile AA metabolite(s). The role of both extracellular and
intracellular calcium in the overall process is unfortunately difficult
to dissect, because the response of the tissue not only to EGF and
TFLLR-NH2 but also to added arachidonate appears
to require the influx of extracellular calcium. Finally, it can be pointed out that the signal process activated by either EGF or TFLLR-NH2 (but not arachidonate) appears to
require the simultaneous (or sequential) activation of both PI3-kinase
and MEK (and presumably, MAP-kinase).
The involvement of both PI3-kinase and MEK in the contractile actions
of EGF and TFLLR-NH2 to cause the contractile
response is in some ways puzzling, because in other circumstances, such as the "growth factor" signal pathways activated by insulin, the downstream events promoted concurrently by either PI3-kinase activation (e.g., insulin-stimulated glucose transport) or by MEK
(insulin-mediated activation of ribosomal S6 kinase) can occur quite
independently of one another. For instance, inhibition of MEK does not
affect insulin-regulated glucose transport, but abrogates
p90rsk1, 2 activation; and under comparable
circumstances, inhibition of PI3-kinase blocks insulin-mediated glucose
uptake, but does not affect insulin-mediated p90rsk1,
2 activation, (an event that is downstream of
MEK/MAP-kinase stimulation). It is thus possible that for
PAR1 and EGF receptor stimulation of the LM
tissue, there may be a linear link between a specific isoform of
PI3-kinase and activation of MEK. This situation for PAR1 activation in the LM tissue would be akin to
the PI3-kinase link between G-protein receptors and MAP-kinase
signaling reported recently by Lopez-Llasaca and coworkers
(Lopez-Llasaca et al., 1997). One scenario to be considered
for EGF is that PI3-kinase may be upstream of the activation of protein
kinase C (see above discussion) and that the PKC-mediated activation of
raf-1 could in turn cause the activation of MEK (Ueda et
al., 1996). Further work is thus indicated with the LM tissue to
determine if a unique PI3-kinase isoform is involved in the
EGF/TFLLR-NH2 signaling process.
A final issue that merits discussion is the potential role that Src may
play in regulating smooth muscle tension. In cell transfection systems,
it now appears that G-protein-coupled agonists such as LPA, via the
participation of the G-protein 
subunit, can cause an activation
of Src; and that this activation of Src is essential for a downstream
activation of MAP-kinase (Luttrell et al., 1996). Further,
it has been suggested that the EGF receptor itself may play a
"scaffolding" role in such a process without acting directly as a
kinase (Luttrell et al., 1997). A similar situation might
take place in the LM tissue preparation. However, the role of
PI3-kinase in such a potential scheme has yet to be elucidated; and it
can be pointed out that interactions between Src itself and PI3-kinase
must also be considered in such a scheme (Pleiman et al.,
1994). Our data demonstrated that Src was indeed activated in the
course of the contractile response driven by either EGF or
TFLLR-NH2; and that the Src-selective tyrosine
kinase inhibitor, CP118,556/PP1 blocked the contractile response to
both agonists. However, CP118,556/PP1 is not completely selective for Src. Additionally, two tyrosine kinase inhibitors (tyrphostin 47/AG213
and genistein) that are poor inhibitors of Src-kinase activity
(Kis in the range > 100 µM: M.D.
Hollenberg and B. Renaux, unpublished data) were, nonetheless quite
good inhibitors of the contractile response in the 8 to 40 µM range.
Our data thus imply that, quite apart from the activation of Src
itself, other nonreceptor tyrosine kinases may be involved in the
tissue response to EGF and TFLLR-NH2. Ongoing
work in our laboratory is aimed at identifying those tyrosine kinases
in addition to Src that may play a role in the rapid regulation of
smooth muscle function.
The authors are grateful to Dr. S. Mokashi for preparing the
antiphosphotyrosine monoclonal antibody (6D9) and the derivatives thereof (conjugated to Sepharose and to horseradish peroxidase) for use
in our study. This article is dedicated to the memory of Dr. Harry
Gregory, the co-discoverer of human epidermal growth factor-urogastrone
(Gregory, 1975).
Amino acids are abbreviated by their one-letter
codes, AA, arachidonic acid;
Cch, carbachol;
CM, circular muscle
preparation;
EGF, epidermal growth factor-urogastrone;
LM, longitudinal
muscle;
LPA, lysophosphatidic acid;
MAPK, mitogen-activated protein
kinase;
MAPKK, mitogen-activated protein kinase kinase, or MEK;
MEK, mitogen-activated protein kinase kinase;
PAR1, protease-activated receptor No. 1 (thrombin receptor);
PAR2, protease-activated receptor No. 2 (activated by
trypsin);
PAR1AP, PAR1-activating peptide;
PAR2AP, PAR2-activating peptide;
PI3K, Phosphatidylinositol 3'-kinase;
PKC, protein kinase C;
PMSF, phenylmethylsulfoxyl fluoride;
TF, TFLLR-NH2.
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Abstract
Introduction
-thrombin in rabbit aortic rings.
Br J Pharmacol
105:
959-967[Medline].
