Department of Pharmacology and Toxicology and the Neuroscience
Program, Michigan State University, East Lansing, Michigan
ATP acts at P2 receptors to contract blood vessels and reactivity to
vasoconstrictor agents is often altered in hypertension. This study was
designed to identify P2 receptors in mesenteric arteries and veins and
to determine whether ATP reactivity is altered in deoxycorticosterone
acetate (DOCA)-salt hypertensive rats. Computer-assisted video
microscopy was used to measure vessel diameter in vitro. ATP was a more
potent constrictor of veins (EC50 = 2.7 µM) than
arteries (EC50 = 196 µM) from normotensive rats;
there was no change in ATP reactivity in vessels from DOCA-salt rats.
The P2X1 receptor agonist 
,
-methylene ATP
(,-MeATP, 0.03-3 µM) contracted arteries but not veins.
ATP-induced contractions in arteries were blocked by ,-MeATP (3 µM) desensitization. 2-Methylthio-ATP (0.1-10 µM), an agonist that
can act at P2Y1 receptors, did not contract arteries or
veins, whereas UTP, an agonist at rat P2Y2/P2Y4
receptors, contracted veins (EC50 = 15 µM) and
arteries (EC50 = 24 µM). UTP-induced contractions of
veins cross-desensitized with ATP, whereas UTP-induced contractions in
arteries were unaffected by ,-MeATP-desensitization. The P2X/P2Y1 receptor antagonist
pyridoxal-phosphate-6-azophenyl-2',4-disulfonic acid blocked
ATP-induced contractions of arteries (IC50 = 4.8 µM)
but not veins. Suramin, an antagonist that blocks P2Y2
receptors, partly inhibited ATP- and UTP-induced contractions of veins.
Immunohistochemical studies revealed P2X1 receptor
immunoreactivity in arteries but not veins. These data indicate that
mesenteric vascular reactivity to ATP is not altered in DOCA-salt
hypertension. ATP acts at P2X1 and P2Y2
receptors to contract mesenteric arteries and veins, respectively,
whereas in arteries UTP acts at an unidentified P2 receptor.
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Introduction |
There
are two classes of receptors for ATP: P2X and P2Y receptors (Fredholm
et al., 1994
). P2X receptors are ligand-gated cation channels that
mediate fast and, in some cases, rapidly desensitizing responses. There
are seven P2X subunits each containing two membrane spanning domains
(Fredholm et al., 1994; North and Surprenant, 2000).
P2X1 receptors are localized to arterial smooth muscle cells where they mediate contraction (Lewis et al., 1998; Hansen
et al., 1999). Furthermore, neurogenic contractions of many arteries
are inhibited by antagonists that block P2X1
receptors or by selective P2X1 receptor
desensitization. Pyridoxal-phosphate-6-azophenyl-2',4-disulfonic acid
(PPADS) is an antagonist that blocks P2X1
receptors (Ziganshin et al., 1994) and ,-MeATP is an agonist at
P2X1 receptors (Surprenant and North, 2000).
Because P2X1 receptors desensitize rapidly, ,-MeATP-induced desensitization can be used to identify responses mediated at P2X1 receptors.
P2Y receptors are a family of G-protein-coupled receptors (Fredholm et
al., 1997). In the vasculature, ATP can act at
P2Y1, P2Y2, or
P2Y4 receptors to alter vasomotor tone (Kunapuli
and Daniel, 1998). 2-Methylthio-ATP (2-Me-S-ATP) is more a potent agonist than ATP at P2Y1 receptors than other
classes of P2Y receptors (O'Connor et al., 1991) and PPADS blocks
P2Y1 receptors (Ralevic and Burnstock, 1996) but
not P2Y2 or P2Y4 receptors
(Charlton et al., 1996a,b; Bogdanov et al., 1998). UTP is inactive at
P2Y1 receptors, whereas UTP and ATP are
equipotent as agonists at rat P2Y2 and
P2Y4 receptors (Bogdanov et al., 1998; Webb et
al., 1998; Williams and Jarvis, 2000). However, suramin blocks
P2Y2 but not P2Y4 receptors
and can be used to discriminate responses mediated at these two
receptors (Bogdanov et al., 1998). Although it is known that ATP
contracts veins (Ohara et al., 1998), the receptor mechanism mediating
this response has not been clearly established.
Changes in reactivity to vasoconstrictor substances often occur in
tissues obtained from hypertensive animals. However, there are marked
differences in the direction of the change (increase, decrease, or no
change) that can depend on the hypertension model and on the blood
vessels or vascular bed studied. For example, there is an increased
sensitivity to the contractile effects of norepinephrine in thoracic
aortae taken from spontaneously hypertensive rats (SHRs) (Lograno et
al., 1989), whereas there are no changes in norepinephrine sensitivity
in mesenteric arteries from SHRs (Naito et al., 1998). However,
mesenteric arteries from two kidney, one clip or one kidney, one clip
(Deng and Schiffrin, 1991) or deoxycorticosterone-acetate (DOCA)-salt
hypertensive rats (Suzuki et al., 1994) show enhanced norepinephrine
reactivity compared with arteries taken from normotensive rats. There
is also variation in reactivity to ATP in veins from hypertensive
animals or humans. Mesenteric veins, but not arteries, from SHRs
exhibit increased reactivity to ATP (Naito et al., 1998), whereas
cutaneous hand veins from hypertensive human subjects were less
reactive to ,-MeATP compared with responses in tissues from
normotensive subjects (Lind et al., 1997). Therefore, it not clear
whether there is a general change in vascular reactivity in
hypertension or whether changes are specific for individual vascular
beds and the hypertensive model. The purpose of the present study was
2-fold. First, these studies were done to identify the receptor
mechanism mediating ATP-induced contractions of mesenteric veins and to
compare this receptor mechanism with that in mesenteric arteries.
Second, these studies were done to determine whether there is change in
reactivity to ATP in mesenteric arteries and veins in the DOCA-salt
model of experimental hypertension in rats. These latter studies were undertaken because sympathetic tone to the venous side of the circulation is elevated in DOCA-salt hypertensive rats (Fink et al.,
2000). As ATP is released from perivascular sympathetic nerves (Burnstock and Kennedy, 1986; Kennedy, 1996), there may be changes in
venous reactivity to ATP.
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Materials and Methods |
DOCA-Salt Hypertension.
Male Sprague-Dawley rats (Charles
River, Inc., Portage, MI) weighing 175 to 225 g were maintained
according to standards approved by the Michigan State University
All-University Committee on Animal Care and Use. Standards were in
strict accordance with Michigan State University and National
Institutes of Health animal care guidelines. All rats were kept in a
light- and temperature-controlled room and housed in clear plastic
boxes in groups of three with free access to standard pelleted rat chow
(Harlan/Teklad 8640 Rodent Diet) and tap water.
After arrival in the animal care facility, rats were acclimatized to
their environment for 2 days before surgical manipulation. DOCA-salt
hypertension was induced by using established methods (Ormsbee and
Ryan, 1973). Briefly, rats were unilaterally nephrectomized under
anesthesia with sodium pentobarbital (45 mg/kg; Abbott Laboratories, Chicago, IL) administered i.p. Bronchiolar secretions were controlled by administration of atropine sulfate i.p. (0.04 mg/kg; Sigma, St.
Louis, MO). Silicone rubber patches (Dow Corning, Ferndale, MI)
impregnated with DOCA (Sigma) were implanted s.c. in rats providing
DOCA at 150 mg/kg. Postoperative analgesia was provided by a single
injection of butorphanol tartrate s.c. (0.5 mg/kg; Abbott
Laboratories). All DOCA-implanted rats were placed on saltwater containing 1% NaCl and 0.2% KCl (DOCA-salt). Normotensive control rats (SHAM) were unilaterally nephrectomized and placed on tap water.
All rats were provided standard pelleted rat chow. Blood pressure was
measured using the tail cuff method 4 weeks after surgery and rats were
used for in vitro studies at this time.
Measurement of Venoconstriction in Vitro.
Rats were killed
using a lethal pentobarbital injection, i.p. The ileum was removed from
the animal and placed in oxygenated (95% O2, 5%
CO2) Krebs' solution of the following
composition: 117 mM NaCl, 4.7 mM KCl, 2.5 mM
CaCl2, 1.2 mM MgCl2, 25 mM
NaHCO3, 1.2 mM
NaH2PO4, and 11 mM glucose.
An ileal segment was placed in a Petri dish and the mesentery was
stretched gently and pinned flat. A section of mesentery close to the
ileal wall was carefully cut free from the intestine and the mesentery
was then transferred to a small silastic-lined recording bath (1.5-ml
volume). Mesenteric fat was carefully dissected away from a secondary
artery or vein to expose the edges of the blood vessel. The recording
chamber was mounted on the stage of an inverted microscope (Olympus
CK-2) and the chamber was superfused continuously with warm (36°C)
Krebs' solution at a flow rate of 7 ml/min. The output of a black and white video camera (KP-111; Hitachi, Tokyo, Japan) attached to the
microscope was fed to a PCVision Plus frame-grabber board (Imaging
Technology Inc., Bedford, MA) mounted in a personal computer. The video
images were analyzed using Diamtrak software (Nield, 1989), which
tracks the distance between the outer edges of the blood vessel in the
observation field. The digitized signal was converted to an analog
output (DAC-02 board; Keithley Metrabyte, Taunton, MA) and fed to a
strip chart recorder (EasyGraph; Gould Inc., Cleveland, OH). The
sampling rate was 10 Hz and changes in blood vessel diameter of 0.5 µm were resolved.
Experimental Protocols.
After mounting on the microscope
stage and beginning superfusion of Krebs' solution, the preparations
were allowed to equilibrate for 20 to 30 min. During this time,
arteries and veins relaxed to a stable resting diameter of between 150 and 220 µm. Drugs were added in known concentrations to the
superfusing Krebs' solution and were applied using an array of
three-way stopcocks. In most experiments, agonists were applied for 2 to 4 min and there was a 10-min interval between successive
applications of agonist. A single agonist concentration-response curve,
either in the absence or presence of antagonist was obtained in each
preparation. Antagonists were applied for a minimum of 20 min before
testing agonist effects in the continued presence of antagonist.
Concentrations of antagonists causing half-maximal inhibition of
ATP-induced contractions were obtained by testing increasing
concentrations of antagonist, applied in a cumulative manner, against a
maximum ATP concentration (100 µM in veins, 1 mM in arteries).
Data Analysis.
Agonist-induced contractions were measured in
micrometers and are expressed as a percentage of the initial resting
diameter of the blood vessel. Half-maximal effective agonist
concentrations (EC50) and maximum responses
(Ymax) were calculated from a
least-squares fit of individual agonist concentration response curves
using the following logistic function from Origin 5.0 (Microcal
Software Inc., Northampton, MA):
where Ymin and n are
the minimum response and slope factor, respectively. All data are
expressed as the mean ± S.E.M. Differences between groups were
assessed by the Kruskal-Wallis nonparametric analysis of variance and
Dunn's multiple comparison test using GraphPad InStat, version 3.0, for Windows 95 (GraphPad Software, San Diego, CA). The n
values refer to the number of animals from which the data were obtained.
Immunohistochemical Procedures.
Mesenteric arcades were
stretched tightly in a Sylgard-lined Petri dish using insect pins. A
30-gauge hypodermic needle was used to cannulate the primary vein and
the arcade was flushed with phosphate-buffered saline (PBS, 0.01 M, pH
7.2). The tissues were then stretched tightly on small piece of balsa
wood using insect pins and were immersed in Zamboni fixative (4%
formaldehyde, 2% picric acid in 0.1 M phosphate buffer, pH 7.4)
overnight at 4°C. The tissues were then cleared three times at 10-min
intervals with dimethyl sulfoxide and washed three times at 10-min
intervals with PBS. Mesenteric arteries and veins were then dissected
from mesenteric fat and incubated overnight in diluted (1:200 in PBS) antiserum raised in rabbits against amino acids 382 to 399 of the rat
P2X1 receptor sequence (Alomone Laboratories,
Jerusalem, Israel). Tissues were washed in PBS and then incubated with
goat anti-rabbit IgG conjugated to tetramethyl rhodamine isothiocyanate (1:40 dilution in PBS; Chemicon International, Temecula, CA) or to
fluorescein isothiocyanate (1:40 dilution in PBS; Sigma) for 1 h.
The tissues were washed again with PBS and then mounted on microscope
slides and coverslipped using buffered glycerol (pH 8.6). Control
studies were conducted by omitting the primary antibody from the
protocol or by incubating tissues with primary antibody that had been
preincubated for 1 h with 1 µg of the antigen peptide (obtained
from Alomone Laboratories). Fluorescent images were acquired using a
Leitz Laborlux S upright microscope, a PL Fluotar 40× objective (0.7 numerical aperture), a SPOT-2 cooled color digital camera
(Diagnostic Instruments, Sterling Heights, MI), and Adobe Photoshop 5.5 software (Adobe Systems, Inc., San Jose, CA).
Drugs.
2-Methylthio-ATP and PPADS were obtained from
Research Biochemicals International (Natick, MA). All other drugs were
obtained from Sigma.
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Results |
Data were obtained from 51 SHAM rats and 45 DOCA-salt rats. The
mean arterial pressure for SHAM rats was 126 ± 7 mm Hg, whereas the mean arterial pressure for DOCA-salt rats was 193 ± 5 mm Hg. The outside diameter of mesenteric arteries and veins examined in this
study ranged between 150 and 230 µm.
ATP Contracts Mesenteric Veins and Arteries.
ATP produced
concentration-dependent contractions of mesenteric veins and arteries
from SHAM and DOCA-salt rats. Contractions caused by ATP in arteries
desensitized almost completely in the presence of higher concentrations
of ATP, whereas in veins the contractions desensitized more slowly and
incompletely (Fig. 1). Comparison of ATP
concentration-response curves obtained in arteries and veins revealed
that ATP was 20- to 70-fold more potent in contracting veins compared
with arteries but the maximum contraction caused by ATP was greater in
arteries than in veins (Fig. 2; Table 1).
There were no differences in ATP
concentration-response curves obtained in veins taken from SHAM rats
compared with those obtained from DOCA-salt rats. Similarly, there were
no differences between ATP concentration-response curves in arteries
from SHAM rats compared with concentration-response curves obtained in
arteries from DOCA-salt rats (Fig. 2; Table 1).
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Fig. 1.
Representative traces of ATP-induced contractions of
mesenteric arteries and veins from SHAM rats. A, responses obtained in
a mesenteric artery desensitized in the continued presence of ATP. B,
responses in a mesenteric vein were smaller in peak amplitude but were
largely maintained throughout the period of ATP application. For both
figures, ATP was applied at the indicated concentrations during the
period indicated by the bar above each trace.
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Fig. 2.
Concentration-response curves for ATP-induced
contractions of mesenteric arteries and veins in preparations taken
from SHAM normotensive and DOCA-salt hypertensive rats. ATP was more
potent in contracting veins than arteries but there were no differences
in sensitivity to ATP associated with DOCA-salt hypertension. Data are
mean ± S.E.M. and n indicates the number of
animals from which the data were obtained.
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TABLE 1
Comparison of ATP EC50 values and maximum response amplitudes
in arteries and veins from sham normotensive and DOCA-salt hypertensive
rats
Data are mean ± S.E.M.; n refers to the number of
animals from which data were obtained.
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,-MeATP Contracts Arteries but Not Veins.
The
above-mentioned data indicate that arteries and veins are
differentially sensitive to the contractile effects of ATP and this
difference could be due to differential expression of P2 receptor
subtypes in mesenteric arteries and veins. It has been shown previously
that rat mesenteric arteries express the P2X1 receptor subtype and ,-MeATP is an agonist at this receptor (Lewis et al., 1998). Therefore, ,-MeATP concentration-response curves were obtained in arteries and veins to determine whether these
blood vessels were differentially sensitive to this agonist. ,-MeATP caused a concentration-dependent contraction of
mesenteric arteries but there were no differences in the curves
obtained in tissues from SHAM and DOCA-salt rats (Fig.
3). The ,-MeATP EC50 values obtained from SHAM and DOCA-salt
tissues were 0.3 ± 0.1 µM (n = 7) and 0.9 ± 0.4 µM (n = 5), respectively (P > 0.05). The maximum responses caused by ,-MeATP were not different
between SHAM and DOCA-salt arteries (Fig. 3). ,-MeATP (up to 3 µM) did not cause more than 10% contraction in veins from either
SHAM or DOCA-salt rats (Fig. 3).
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Fig. 3.
Concentration-response curves for the P2X receptor
agonist ,-MeATP in mesenteric arteries and veins in preparations
taken from SHAM normotensive and DOCA-salt hypertensive rats. The data
show that ,-MeATP causes contractions of arteries but not veins
and there were no differences in ,-MeATP sensitivity between SHAM
and DOCA arteries. Data are mean ± S.E.M. and n
indicates the number of animals from which the data were obtained.
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A cross-desensitization protocol was used to determine whether
,-MeATP and ATP were acting at the same receptor to cause contraction of mesenteric arteries. A control response to a maximum concentration of ATP (1 mM) was obtained (Fig.
4A, left). After ATP washout and
recovery, ,-MeATP (3 µM) was applied and the response was
allowed to desensitize. In the continued presence of
,-MeATP-induced desensitization, ATP was reapplied (Fig. 4A,
middle). In these experiments, the ATP-induced contraction was reduced
by more than 80% after ,-MeATP-mediated desensitization (Fig.
4B). After washing out ,-MeATP for 20 to 40 min, the ATP response
fully recovered [Fig. 4, A (right) and B].
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Fig. 4.
ATP and ,-MeATP exhibit cross desensitization
in mesenteric arteries. A, representative traces of ATP- and
,-MeATP-induced contractions of mesenteric arteries in the
cross-desensitization protocol. In the presence of
,-MeATP-induced desensitization, ATP did not contract arteries.
The ATP response recovered 20 min after ,-MeATP washout. B,
pooled data from experiments shown in A, demonstrating that
,-MeATP-induced desensitization significantly inhibited
ATP-induced contractions in a reversible manner.
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UTP but Not 2-Me-S-ATP Contracts Mesenteric Veins and
Arteries.
UTP and 2-Me-S-ATP can act as P2Y receptor agonists.
Therefore, these drugs were used to determine whether P2Y receptors
mediate contraction of mesenteric veins. In a concentration range
(0.1-10 µM) that would activate P2Y receptors (Ralevic and
Burnstock, 1996), 2-Me-S-ATP caused less than a 20% constriction of
arteries or veins in tissues from SHAM and DOCA-salt rats (Fig.
5A). 2-Me-S-ATP (0.1-10 µM)
concentration-response curves in SHAM arteries and veins were
unaffected following pretreatment of tissues for 20 min with
indomethacin (10 µM) and nitro-L-arginine (100 µM). At 10 µM, 2-Me-S-ATP caused a 16 ± 4% in veins (n = 7) and a 4.5 ± 3% contraction in arteries (n = 3) in indomethacin- and
nitro-L-arginine-pretreated tissues. These values
were not different from those obtained in normal Krebs' solution (Fig.
5A, P > 0.05). At concentrations greater than 10 µM
2-Me-S-ATP did cause contractions of mesenteric arteries studied in
normal Krebs' solution (data not shown).
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Fig. 5.
UTP but not 2-Me-S-ATP caused contractions of
mesenteric veins. A, 2-Me-S-ATP concentration-response curves obtained
in mesenteric arteries and veins. 2-Me-S-ATP produced less than 20%
maximum contraction in all blood vessels. B, UTP concentration-response
curves in mesenteric arteries and veins. Data in both figures are
mean ± S.E.M. and n indicates the number of
animals from which the data were obtained.
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UTP (1-300 µM) caused a concentration-dependent contraction of veins
that was similar in amplitude to the contraction caused by ATP. UTP was
equipotent in causing contractions of arteries and veins and there was
no change in vascular UTP sensitivity associated with DOCA-salt
hypertension (Fig. 5B). The EC50 values for UTP
in SHAM and DOCA-salt veins were 15 ± 4 (n = 5)
and 35 ± 9 (n = 6) µM, respectively. The UTP
EC50 value obtained in SHAM veins was not
different from the ATP EC50 values obtained in
SHAM and DOCA veins (P > 0.05, Table 1). The UTP
EC50 value obtained in DOCA veins was
significantly greater than ATP EC50 values
obtained in SHAM and DOCA veins (P < 0.05, Table 1).
The EC50 values for UTP in SHAM and DOCA-salt
arteries were 24 ± 5 (n = 5) and 23 ± 4 (n = 3) µM, respectively. There were no differences
in the maximum responses caused by UTP in arteries or veins (Fig. 5B).
ATP and UTP Cross-Desensitize in Mesenteric Veins but Not
Arteries.
The response caused by 300 µM ATP in mesenteric veins
desensitized slowly and incompletely (Fig.
6). However, after the ATP response had
declined to a stable plateau, the UTP (100 µM) response was markedly
reduced in amplitude and the combined ATP/UTP contraction reached the
amplitude of the contraction caused by UTP alone (Fig. 6). The control
UTP contraction was 29.5 ± 2%, whereas after ATP desensitization
the response amplitude was 18 ± 3% (n = 5, P < 0.02). The UTP response recovered to 26 ± 3% after ATP washout. In contrast, when ,-MeATP (3 µM) was
used to desensitize P2X receptors in arteries, there was no
cross-desensitization between the UTP and ,-MeATP (Fig.
7). In arteries, the control UTP (100 µM) response was 42 ± 9% and after ,-MeATP
desensitization, the UTP response was 47 ± 4% (n = 5, P > 0.05).
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Fig. 6.
ATP- and UTP-induced responses cross-desensitized in
mesenteric veins. UTP-induced contraction was reduced in amplitude
during partial desensitization caused by continuous application of ATP.
The UTP response recovered after ATP washout. Agonists were
applied during the period indicated by the bar above the traces.
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Fig. 7.
There was no cross-desensitization between responses
caused by UTP and ,-MeATP in mesenteric arteries. The UTP
response was similar in amplitude before and after ATP
desensitization.
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Antagonist Inhibition of ATP- and UTP-Induced Contractions in
Arteries and Veins.
To further test the hypothesis that the P2
receptors mediating contractions of arteries and veins are different,
PPADS and suramin were used in attempt to block ATP-induced
contractions of mesenteric blood vessels. Increasing concentrations of
PPADS (0.1-30 µM) were applied in a cumulative manner to test for
inhibition of the contraction caused by maximum concentrations of ATP
(1 mM in arteries, 100 µM in veins). PPADS produced a
concentration-dependent inhibition of ATP-induced contractions in
arteries (IC50 = 4.8 ± 1.8 µM,
n = 4) but not in veins (Fig.
8, A and B). PPADS also did not inhibit
UTP (100 µM)-induced contractions of mesenteric veins (Fig. 8B).
Increasing concentrations of suramin (3-300 µM) were applied in a
cumulative manner in an attempt to block ATP- or UTP-induced (each at
100 µM) contractions of veins. It was found that suramin inhibited
the contractions caused by ATP and UTP by a maximum of approximately
50% (Fig. 9).
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Fig. 8.
PPADS blocked ATP-induced contractions of mesenteric
arteries but not veins, whereas suramin blocked contractions in veins.
A, representative traces of ATP-induced contractions of a mesenteric
artery (top) and vein (bottom) in the absence and presence of
increasing concentrations of PPADS. B, concentration-inhibition curves
for PPADS and suramin against ATP-induced contractions of arteries and
veins. Data are mean ± S.E.M. and n indicates the
number of animals from which the data were obtained.
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Fig. 9.
Suramin partly blocked contractions caused by ATP and
UTP in mesenteric veins. Suramin caused a concentration-dependent
inhibition of contractions caused by ATP (100 µM) and UTP (100 µM).
The maximum inhibition was approximately 50%. Data are mean ± S.E.M. and n indicates the number of animals from which
the data were obtained.
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Immunohistochemical Localization of P2X1 Receptors in
Mesenteric Arteries but Not Veins.
The data summarized above
suggest that there is a differential localization of P2 receptors in
mesenteric arteries and veins and the arteries express a P2X receptor
subtype. An antibody raised against the rat P2X1
receptor was used in an attempt to show that this receptor subtype was
localized to vascular smooth muscle in mesenteric arteries but not
veins. These studies revealed that mesenteric arteries exhibited
P2X1 immunoreactivity that was present in a
punctate pattern in the wall of arteries but not veins (Fig. 10, observations were obtained in
artery and vein preparations from three SHAM rats and three DOCA-salt
rats). There was no obvious difference in the staining pattern of
arteries from SHAM or DOCA-salt rats. The staining was absent if the
primary antibody was omitted from the staining protocol or if the
primary antibody was preincubated with the antigen peptide.
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Fig. 10.
Immunoreactivity for the P2X1 receptor
was detected in mesenteric arteries but not veins. Upper
photomicrograph shows the discrete localization P2X1
receptor immunoreactivity in a mesenteric artery. No P2X1
immunoreactivity was detected in an adjacent mesenteric vein (lower
photomicrograph; calibration bar, 50 µm).
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Discussion |
Reactivity to ATP Is Not Altered in DOCA-Salt Hypertension.
It
has been shown previously that reactivity to norepinephrine acting at
1-adrenergic receptors is increased in
mesenteric arteries from DOCA-salt hypertensive rats (Ekas and
Lukhandwala, 1980; Perry and Webb, 1988; Suzuki et al., 1994). As
norepinephrine is released from sympathetic nerves associated with
mesenteric arteries, increased vascular reactivity would result in
increased vasoconstriction and elevated blood pressure (de Champlain,
1990). ATP is a cotransmitter released with norepinephrine from
sympathetic nerves and ATP contracts arterial smooth muscle (Burnstock
and Kennedy, 1986; Kennedy, 1996). Therefore, it might be expected that
ATP reactivity would be increased in arteries from DOCA-salt hypertensive rats as occurs for norepinephrine. However, it was found
that there were no differences in the sensitivity of mesenteric arteries to the contractile effects of ATP in tissues from DOCA-salt rats. Similar data have been obtained in mesenteric arteries from SHRs
(Naito et al., 1998), indicating that an increase in arterial reactivity to ATP does not contribute to the increase in sympathetic tone to arteries in these two models of hypertension. Although there
have been few studies of altered reactivity in veins from hypertensive
animals, increased venoconstriction would cause a transient increase in
cardiac output and also shift blood from the capacitance to the
resistance side of the circulation. Both of these changes would
increase blood pressure. Therefore, studies of venous reactivity are
potentially important in identifying cardiovascular changes underlying
hypertension. In the present study, it was shown that mesenteric veins
contract in response to ATP but that there were no differences in
reactivity between veins taken from SHAM or DOCA-salt rats. This is an
important observation as venomotor tone is elevated in DOCA-salt
hypertensive rats and this increased tone is due partly to increased
sympathetic input to veins (Fink et al., 2000). These data suggest
that, if ATP is a cotransmitter released with norepinephrine from
sympathetic nerves associated with mesenteric veins, increases in
venous smooth muscle reactivity to ATP do not contribute to increased
venomotor tone in DOCA-salt hypertensive rats.
Although receptor mechanisms and functional responses caused by P2
receptor activation in tissues maintained in vitro or in situ have the
subject of numerous studies, integrated hemodynamic responses to P2
receptor activation in vivo are less well defined. Activation of P2X
receptors increases blood pressure and vascular resistance in hindlimb,
mesenteric, and renal circulations in anesthetized rats (Cox and Smits,
1996). Alternatively, P2Y1 receptor activation
following treatment of anesthetized rats with 2-Me-S-ATP decreases
blood pressure and vascular resistance (Cox and Smits, 1996). Blockade
of P2 receptors following intravenous administration of PPADS to
anesthetized rats increased mean arterial pressure fluctuations,
suggesting that ATP released from sympathetic nerves functions in part
to stabilize arterial pressure (Golubinskaya et al., 1999). Taken
together, these data suggest an important contribution of
P2X1 receptor function to the control of arterial diameter
and systemic blood pressure (Golubinskaya et al., 1999). The
contribution of P2 receptor activation on venous smooth muscle to
integrated venous function and overall hemodynamics has not been studied.
Differential Localization of P2 Receptors in Arteries and
Veins.
ATP acts at P2X1 receptors to
contract arterial smooth muscle (Lewis et al., 1998). These conclusions
are supported by data from the present study that show ATP-induced
contractions desensitize rapidly, are mimicked by ,-Me-ATP,
cross-desensitize with ,-Me-ATP, and are blocked by PPADS. These
are all properties of responses mediated at vascular
P2X1 receptors (Fredholm et al., 1994; Ziganshin et al., 1994; Kunapuli and Daniel, 1998). However, the receptor mechanism for ATP-induced contractions of veins was different. First,
ATP responses in veins desensitized slowly and incompletely. Second,
,-Me-ATP did not contract mesenteric veins and ATP-induced contractions in mesenteric veins were resistant to inhibition by PPADS.
Finally, immunohistochemical studies demonstrated the presence of
P2X1 immunoreactivity in mesenteric arteries, as
also shown by Hansen et al. (1999), but not veins. These data indicate that mesenteric veins do not express P2X1 receptors.
Several P2Y receptor subtypes are present in the vasculature.
Biochemical and molecular biological studies have shown that P2Y1, P2Y2, and
P2Y4 receptors are expressed by endothelial cells and these
receptors couple to the production and release of vasodilator prostanoids and nitric oxide (Kunapali and Daniel, 1998). Data from
functional studies in the rat mesenteric vasculature indicate that
P2Y1 and P2Y2 receptors
couple to activation of nitric-oxide synthase (Ralevic and Burnstock,
1991, 1996). P2Y2 and P2Y4
receptors are expressed by vascular smooth muscle cells and stimulation of these receptors causes smooth muscle contraction (Kunapali and
Daniel, 1998). The data presented here are consistent with localization
of P2Y2 receptors to the smooth muscle layer of
rat mesenteric veins. This conclusion is based on the following
observations. 2-Me-S-ATP is a more potent agonist than ATP at
P2Y1 receptors (Fredholm et al., 1994) but
2-Me-S-ATP at concentrations that would activate
P2Y1 receptors (Ralevic and Burnstock, 1996;
Barnard, 2000) produced little or no response in mesenteric veins. High concentrations (>10 µM) of 2-Me-S-ATP contracted mesenteric
arteries. However, because ATP and 2-Me-S-ATP are equipotent at
stimulating P2X1 receptors (Surprenant and North,
2000), contractions caused by high concentrations of 2-Me-S-ATP were
likely due to an action at P2X1 receptors. As
P2Y1 receptors on endothelial cells can cause
release of vasodilator prostanoids and/or nitric oxide (see above), it
is possible that contractions caused by 2-Me-S-ATP acting at
P2Y1 receptors were masked by a simultaneous
vasodilator response. However, 2-Me-S-ATP concentration-response curves
were unaffected following pretreatment of tissues with indomethacin to
block cyclooxygenase and nitro-L-arginine to block
nitric-oxide synthase. Finally, PPADS can block P2Y1
receptors (Ralevic and Burnstock, 1996) but ATP-induced contractions of
mesenteric veins were resistant to PPADS antagonism. Taken together,
these data lead to the conclusion that that smooth muscle cells in rat
mesenteric veins do not express contractile P2Y1 receptors.
UTP is equipotent with ATP as an agonist at P2Y2
receptors and rat P2Y4 receptors (Fredholm et
al., 1994; Bogdanov et al., 1998) and in the present study UTP and ATP
were equipotent in contracting veins from SHAM rats. Suramin blocks
P2Y2 but not P2Y4 receptors
(Charlton et al., 1996a,b; Bogdanov et al., 1998) and this antagonist
was used to identify the contractile P2Y receptor in mesenteric veins.
It was found that suramin partly inhibited contractions of mesenteric
veins caused by both ATP and UTP. Finally, responses caused by ATP and
UTP in mesenteric veins showed cross-desensitization, indicating that
these agonists acted at the same receptor site. Overall, these data
indicate that in the rat mesentery ATP acts at
P2Y2 receptors to cause venoconstriction. Ohara
et al. (1998) concluded previously that P2U receptors mediate
ATP-induced contractions of perfused mesenteric veins from the rat. P2U
receptors are now classified as P2Y2 receptors
(Communi and Boeynaems, 1997). Because suramin produced only a partial
inhibition of ATP- and UTP-induced contractions of mesenteric veins, it
is likely that another P2 receptor type contributes to these responses
as well.
UTP Responses in Mesenteric Arteries.
UTP caused contractions
of mesenteric arteries that persisted after ,-Me-ATP-induced
desensitization of P2X1 receptors. These data,
and those published previously by others (Juul et al., 1992), suggest
that UTP acts at an additional P2 receptor in mesenteric arteries to
cause contractions. There is evidence for a UTP preferring
"pyrimidine" receptor in sympathetic neurons (Connolly, 1994),
cardiac endothelial cells (Yang et al., 1996), and in the rat aorta
(Garcia-Velasco et al., 1995). However, the UTP-preferring receptor
does not appear to be a member of a separate class of receptors and it
is likely to be a P2Y receptor subtype (Communi and Boeynaems, 1997).
ATP is a cotransmitter released from peri-arterial sympathetic nerves
and P2X1 receptors are the target for
nerve-released ATP in mesenteric arteries. The ATP-insensitive, UTP-preferring receptor in mesenteric arteries may be activated by
vasoactive nucleotides released by nonadrenergic perivascular nerves or
by non-neuronal sources.
Conclusions.
The data presented here indicate that ATP
contracts mesenteric veins and arteries and that reactivity to ATP in
mesenteric arteries and veins is not altered in tissues from DOCA-salt
hypertensive rats. In addition, the receptor mechanism mediating
ATP-induced contraction is different in arteries and veins. The data
indicate that P2X1 receptors mediate ATP-induced
contractions of mesenteric arteries and P2Y2
receptors mediate ATP-induced contractions of mesenteric veins. These
data support the concept that vasomotor activity on the arterial and
venous sides of the circulation can be targeted selectively by drugs
acting at receptors uniquely expressed by arterial or venous smooth
muscle cells.
This work was supported by Grant-in-Aid 9808095W from the
American Heart Association, Mid-West Affiliate, and by National Institutes of Health Grants HL63973 and HL24111. M.C.H. and S.B.M. were
recipients of American Heart Association, Mid-West Affiliate Student
Research Fellowships.
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Abstract
Introduction
![y={(Y<SUB><UP>min</UP></SUB>−Y<SUB><UP>max</UP></SUB>)/[1+(x/<UP>EC</UP><SUB><UP>50</UP></SUB>)<SUP>n</SUP>]}+Y<SUB><UP>max</UP></SUB>](/content/vol296/issue2/fulltext/478/img001.gif)
a nanomolar affinity antagonist at rat mesenteric artery P2X receptor ion channels.
Br J Pharmacol
124:
1463-1466[Medline].
