Division of Biochemistry, School of Medicine, University of
Tasmania, Hobart, Tasmania, Australia 7001
Norepinephrine (NE) induces a sigmoidal dose-response curve for
perfusion pressure and a bell-shaped curve for oxygen consumption (VO2) in the constant-flow perfused hindlimb of Wistar
rats. These effects are now described in spontaneously hypertensive
rats (SHR) and age-matched Wistar-Kyoto rats (WKY). In SHR, the
pressure curve was shifted left- and upward whereas the VO2
curve was shifted left- but downward, when compared with WKY. In the
presence of 10 µM propranolol, prazosin (2.5 nM) shifted the pressure
and VO2 curves much more than yohimbine (0.1 µM) to the
right in both strains and its effects were greater in SHR, suggesting
that these effects were mediated largely by alpha-1
receptors, particularly in SHR. In the presence of propranolol plus
yohimbine, the pressure curve was markedly shifted to the right by both
the selective alpha-1A-antagonist 5-methylurapidil (3.3 nM), and by the alpha-1D antagonist BMY 7378 (0.1 µM)
or SK&F 105854 (2 µM) in SHR but not in WKY. With respect to the
VO2 curve, 5-methylurapidil attenuated the descending limb
without affecting the ascending limb. Similar effects were also
obtained with another alpha-1A antagonist 1 nM KMD-3213
in both SHR and WKY. In contrast, BMY and SK&F markedly inhibited the
ascending limb of the VO2 curve. These results indicate that both alpha-1A- and alpha-1D subtypes
are functionally up-regulated in SHR muscle vascular bed where the
ascending limb of VO2 is predominantly mediated by the
alpha-1D at a much lower concentration for NE than the
descending limb which is predominantly mediated by the
alpha-1A subtype.
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Introduction |
Studies
in humans and animals have indicated a close link between hypertension
and obesity. While one of the major causes for hypertension is an
increased peripheral vascular resistance, obesity is due to either an
excessive energy intake, a decreased energy expenditure or both. Both
peripheral vascular resistance and energy metabolism are regulated by
the sympathetic nervous system (Reaven, 1995
).
In skeletal muscle, the largest and potentially most important
thermogenic tissue, the sympathetic nervous system controls thermogenesis through both 
and 
ARs by different mechanisms. Whereas -ARs directly mediate VO2 (an indirect
measure of thermogenesis) in muscle cells, -ARs appear to control
muscle VO2 by hemodynamic mechanisms (Ye et
al., 1995). In the constant-flow perfused hindlimb of Wistar rats,
a reliable muscle vascular preparation with many characteristics
similar to those in vivo (Bonen et al., 1994), administration of 1-AR agonists or sympathetic nerve stimulation elicits either positive or negative changes in
VO2 during a sigmoidal increase in perfusion
pressure, an indicator of vasoconstriction in this model (Clark
et al., 1995; Hall et al., 1997). One of the
major features of -AR mediated VO2 is its
bell-shaped dose-response curve characterized by increases (the
ascending limb) at low concentrations of norepinephrine (LNE, <1 µM)
and decreases from the maximum to a value below the basal level (the
descending limb) at high concentrations of NE (HNE > 1 µM)
(Dora, 1993; Rattigan et al., 1995; Clark et al.,
1995). Similarly, sympathetic nerve stimulation raises
VO2 at low frequencies (<4 Hz) but reduces
VO2 at high frequencies (>4 Hz) during
vasoconstriction (Hall et al., 1997). Both the increase and
the decrease in VO2 are reversed when the vasoconstriction is blocked by either -1-AR antagonists or by vasodilators such as nitroprusside (Dora, 1993; Rattigan et
al., 1995; Ye et al., 1995, Hall et al.,
1997). These findings strongly suggest a close link of muscle
VO2 to vasoconstriction mediated by -ARs in
the perfused rat hindlimb.
In the perfused hindlimb of SHR, NE is known to cause stronger
vasoconstriction compared to that in their genetically normotensive counterparts, WKY (Cheng and Shibata, 1980). Similar results were obtained with the 1-AR agonist methoxamine (Adams et al.,
1989). These data suggest that functional changes in -1-ARs may
occur in the resistance blood vessels of muscle vascular beds in SHR. If so, the muscle VO2 (and therefore
thermogenesis) controlled by -1-AR-mediated vasoconstriction is also
likely to be affected.
At least three -1-ARs have so far been identified in vascular
tissues, namely alpha-1A-, alpha-1B- and
alpha-1D-subtypes (Hieble et al., 1995a).
Functional characterization of these subtypes has been made possible
now by using subtype selective antagonists. For instance, all these
three subtypes show a high affinity for prazosin and a low affinity for
yohimbine (Bylund et al., 1994). Both 5 MU (Perez et
al., 1994) and KMD (Shibata et al., 1995) have a higher
affinity for the -1A-AR than for the other two subtypes, whereas BMY
(Goetz et al., 1995) and SK&F (Hieble et al.,
1995b) each possess a higher affinity for the -1D-AR. The -1B-AR
is most sensitive to alkylation by CEC (Minneman et al., 1988, Bylund et al., 1994). We hypothesized that the
increased sensitivity of SHR muscle vascular bed to NE may be mediated
by differently altered -1-AR subtypes and these alterations may then
lead to changes in NE-elicited thermogenesis in this tissue. Therefore,
we compared the effects of seven selective -AR antagonists on
NE-induced vasoconstriction and associated VO2 in
the perfused hindlimb of SHR and their age-matched WKY in our study.
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Materials and Methods |
Animals.
Age-matched (11 wk) male SHR (277.7 ± 1.0 g, n = 36) and WKY (276.2 ± 0.9 g,
n = 36) used for the experiments were purchased from
the Animal Resources Center of Australia. The animals were housed on
arrival at 20°C with a 12 hr light/12 hr dark cycle and allowed free
access to food and water. The diet consisted of 2% protein, 4.6%
lipid, 69% carbohydrate, 6% crude fiber with added vitamins and
minerals (Gibson, Hobart, Tasmania). All experiments were
approved by the Ethics Committee of the University of Tasmania under
the Australian Code of Practice for the Care and Use of Animals for
Scientific Purposes (1990). Blood pressure determined in the
anesthetized state (pentobarbital, 60 mg/kg, i.p) from a cannulated
carotid artery by the use of a manometer (ALPK2, Japan) was much higher
in SHR compared with that in WKY (182 ± 3.0 vs.
94 ± 3.0 mmHg, P < .001, n = 8).
Hindlimb perfusion.
The rats were anaesthetized with sodium
pentobarbital (60 mg/kg i.p.). A midline incision was made to expose
the abdominal cavity and the cut edges of the abdominal wall were
ligated, where necessary, with sutures. Gut, seminal vesicles and
testicles were removed after appropriate ligations. The right common
iliac artery and vein were ligated so that only the left hindlimb was
perfused. To prevent any perfusate spillover when perfusion pressure
was increased, blood vessels connected with tissues other than the left
hindlimb were carefully tied off. These included the right hypogastric
vessels, the left inferior and superficial epigastric vessels, the
inferior mesenteric and superior vesicle vessels, and the iliolumbar
and spermatic vessels on both sides. Before cannulation, heparin (0.5 ml, 1000 U/ml) was injected into the vena cava between the right and
left renal veins. Two cannulae (Ohmeda, Sweden) were then inserted
caudally into the abdominal aorta (16G) and vena cava (18G) between the
left renal and iliolumbar vessels. The rat was then immediately placed
on perspex platform for perfusion followed by an overdose injection of
the anesthetic to kill the animal. Ligatures were then placed firmly
around: the lumbar trunk between
L3-L4 vertebrate, right
thigh (near the inguinal ligament), and the genitalia (above the
penis), respectively.
The perfusate consisting of a modified cell-free Krebs-Ringer
bicarbonate buffer (pH 7.4) containing 8.3 mM glucose, 1.27 mM
CaCl2 and 2% bovine serum albumin was
equilibrated by an artificial lung with a mixture of 95%
O2 and 5% CO2. The basal
perfusion flow was set at 6 ml/min by adjusting the perfusion pump
speed and confirmed by intermittent collection of the venous effluent from the hindlimb. The rat hindlimb was perfused in a nonrecirculating manner at 25°C. The hindlimb perfused under these conditions provides qualitatively similar results to those perfused with erythrocyte containing media at 37°C in its metabolic responses to various vasoconstrictors (Bonen et al., 1994; Clark et
al., 1995). The venous oxygen partial pressure was maintained
above 150 mmHg even at maximal oxygen extraction. Adequate oxygen
delivery at this flow rate had been confirmed in our earlier studies
(Colquhoun et al., 1990). The perfusion was completed within
180 min and our previous experiments under similar conditions have
shown that this preparation was stable for at least this period of time
with similar muscle metabolic characteristics as those in
vivo (Colquhoun et al., 1990). The heart, weighed after
perfusion, showed a 20% increase in SHR compared WKY (1.10 ± 0.01 g vs. 0.90 ± 0.01, P < .01, n = 12).
Perfusion pressure was monitored via a pressure transducer from a side
arm of the arterial line immediately before the arterial cannula.
Oxygen partial pressure of the perfusate was measured by an in-line
Clark-type oxygen electrode, which was calibrated before and after each
perfusion with oxygen and air. The oxygen content in the perfusate was
calculated according to the partial pressure using Bunsen coefficient
for plasma as described previously (Colquhoun et al., 1990).
VO2 by the perfused hindlimb was then calculated
from the arteriovenous difference of oxygen contents multiplied by flow
rate and divided by the mass of perfused muscle. The perfused muscle
mass was measured by weighing dye-containing muscle dissected from
hindlimbs that had been infused with Evan's blue (1% w/v) at the end
of experiment without changing perfusion conditions. The perfused
muscle mass was 23.02 ± 0.56 and 22.18 ± 0.79 g for
WKY and SHR, respectively (P > .05, n = 11). When expressed as ml min
1
g1 muscle, the perfusion flow rate was not
significantly different between WKY and SHR (0.26 ± 0.03 vs. 0.27 ± 0.02, P > .05, n = 11).
Experimental protocols.
After commencing the perfusion, 50 min was allowed to elapse before constructing the dose-response curve
for NE. The basal values for perfusion pressure and
VO2 were obtained between 40 and 50 min. Three
sets of experiments were performed in both SHR and WKY as follows. Set
1 was designed to assess the involvement of -ARs in NE-induced
changes in vasoconstriction and associated VO2 by
comparing the effects of NE in the absence and presence of 10 µM
propranolol. In set 2, experiments were divided to three groups and
conducted in the presence of 10 µM propranolol to evaluate the role
of 1- and 2-ARs in
altered vasoconstriction and VO2 induced by NE:
control (from set 1), prazosin (2.5 nM) and yohimbine (0.1 µM).
Assessments of the contribution of each 1-AR
subtype to the altered vasoconstriction and VO2
were conducted in set 3 in the presence of propranolol (10 µM) plus
yohimbine (0.1 µM). The experiments were assigned to the following
groups: control (from set 2), 5 MU (3.3 nM), KMD (1 nM), CEC (10 µM),
BMY (0.1 µM) and SK&F (2 µM). The doses of these -AR antagonists
were chosen to maximize the differentiation of differences between SHR
and WKY according to our preliminary experiments within the range of
their selectivity. The experiments on SHR and WKY were interspersed
randomly. After obtaining the results from set 3, additional
experiments were performed with low doses of BMY (10 nM) and SK&F (0.33 µM) in SHR to further examine the role of -1D-AR subtype on the
descending limb of the VO2 response curve. Each antagonist was infused 30 min before and during the period of NE
infusion. NE and -AR antagonists were infused from a port in the
arterial line at a rate less than 1% of the perfusion flow rate and
mixed by a magnetic stirrer in a small bubble trap before entering the
hindlimb. In experiments with CEC, the alkylating agent was infused for
a period of 30 min and then washed out for 20 min before the infusion
of NE. Dose-response curves were constructed in a cumulative fashion.
Each hindlimb was used for constructing the dose-response curves only
once to ensure that the metabolic characteristics of the preparation
were valid within the period of time previously established (Colquhoun
et al., 1990). The perfusion flow rate was checked
(corrected if necessary) each time after changing NE dose.
Chemicals.
[-]-NE bitartrate,
dl-propranolol hydrochloride, prazosin hydrochloride and
yohimbine hydrochloride were obtained from Sigma (St. Louis, MO).
5-Methylurapidil, BMY 7378 dihydrochloride, chloroethylclonidine dihydrochloride were purchased from RBI (Natick, MA). KMD-3213 ((-)-(R)-1-(3-hydroxypropyl)-5-[2-[[2-[2-(2,2,2-trifluroroethoxy)phenoxyl]ethyl]amino]propyl]indoline-7-carboxamide) was a gift from Dr. Y. Kurashina (Kissei Pharmaceutical Co., Matsumoto, Japan) and SK&F 105854 (furo-3-ben-zazenpine) a gift from Dr. J. P. Hieble (SmithKline Beecham Pharmaceuticals, King of Prussia, PA). NE
was dissolved freshly in .9% NaCl containing 0.1% ascorbic acid.
Prazosin was initially dissolved in dimethylsulfoxide in a stock
solution and then diluted to an appropriate concentration with 0.9%
NaCl before use. Other antagonists were dissolved in the normal saline.
Bovine serum albumin (fraction V) was obtained from Boehringer Mannheim
Corp. (Indianapolis, IN). Other chemicals were analytical grade from
Ajax Chemicals (Sydney, Australia).
Calculation and statistical analysis.
EC25, EC50 and
IC75 (designated here as the inhibitory effect of
NE on VO2) were calculated individually from the
best fit dose-response curves by Sigma Plot for Windows on the basis of fractional changes (Kenakin, 1993). The regression coefficient closest
to 1 was used to determine the best fitness of a curve. Because
NE-induced changes in VO2 were bell-shaped,
EC25 and IC75 were
calculated instead of EC50 and
IC50 to avoid, where possible, the influence of
one side of the response on the other (Szabadi, 1977). The negative log
values of EC25, EC50 and
IC75 were expressed as
pEC25, pEC50 and
pIC75, respectively (Jenkinson et al.,
1995). pKB values were calculated according
to the following formula (Kenakin, 1993) using
EC50 of perfusion pressure:
pKB = log (DR-1)-log[B], where
DR is the ratio of EC50 in the presence of a
given antagonist to EC50 in absence of
antagonist, and [B] is the concentration of the
antagonist. Because DR could not be obtained from individual hindlimb
preparations, pKB was calculated using the
mean EC50 and was without a S.E. Data are
presented as means ± SE. Dose-response curves were determined to
differ (P < .05) using ANOVA (Startview SE, Abacus Concept,
Berkeley, CA) with dose as a repeated measure. Bell-shaped
dose-response curves were firstly tested using all points. Then each
side of the curves was further analyzed based on the model of two
functionally antagonistic receptor populations activated by the same
agonist (Szabadi, 1977). Student's t tests were used for
the comparison between two means values with P < .05 as
statistically significant.
| |
Results |
Effects of adrenergic antagonists on basal perfusion pressure and
VO2.
None of the antagonists used, when
infused alone, had any significant effect on either the basal perfusion
pressure or VO2 in SHR or WKY (table
1). The calculated basal perfusion
pressure and VO2 from the pooled data were
37.3 ± 0.3 and 7.0 ± 0.1 µmol g1 hr1,
respectively, for WKY (n = 36). In SHR, the basal
perfusion pressure (45.5 ± 0.6 mmHg) and
VO2 (7.9 ± .1 µmol
g1 hr1) were
both significantly higher (P < .01, n = 36).
Effects of NE on perfusion pressure and
VO2.
NE induced a dose-dependent sigmoidal
increase in perfusion pressure in both SHR and WKY (fig.
1). Compared with WKY, the perfusion
pressure was displaced to the left for more than 2-fold in SHR as
indicated by the value of pEC50 (table
2). The maximal increase in pressure
(Pmax) was greater in SHR (235.7 ± 7.5 mmHg, P < .01) than in WKY (199.3 ± 3.1 mmHg). During
vasoconstriction, NE-elicited bell-shaped changes in
VO2 in both strains. Compared with WKY, the
change in VO2 was altered in SHR with the
ascending side increased (P < .05) and descending side depressed
(P < .01, ANOVA). Furthermore, LNE-induced maximal increment in
VO2 (VO2 max) was smaller
(3.65 ± 0.11 vs. 4.41 ± 0.14 µmol
g1 hr1,
P < .01) and HNE-induced maximal inhibition of
VO2 (VO2 min) was greater
(-3.51 ± 0.37 vs. -0.87 ± .43 µmol
g1 hr1,
P < .01) in SHR.
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Fig. 1.
Effects of NE on perfusion pressure and
VO2 in the perfused hindlimb of SHR and WKY. Dose-response
curves were constructed by an accumulative infusion of NE. Basal values
of perfusion pressure and VO2 are shown in table 1. Open
circles, WKY; closed circles, SHR. Data are means ± S.E.
(n = 4). P < .01 for the pressure curves;
P < .05 for the ascending side and P < .01 for the
descending side of the VO2 curves (ANOVA).
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TABLE 2
Effect of - and -AR antagonists on the pEC50 for
perfusion pressure and the pEC25 and pIC75 for
VO2 produced by NE in the perfused hindlimb of SHR and WKY
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Effects of -AR antagonist on NE-induced perfusion pressure and
VO2.
In the presence of propranolol,
NE-induced perfusion pressure was shifted to the left in WKY (fig.
2 A and B; table 2). Although VO2 max was smaller in WKY (5.64 ± 0.18 vs. 4.40 ± 0.20 µmol g1
hr1, P < .01, t test), the entire
VO2 curve was not significantly different (P > .05, ANOVA). Neither pressure nor VO2 produced by NE was significantly altered by propranolol in SHR (fig. 2 C and D).
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Fig. 2.
Effects of propranolol on NE-induced perfusion
pressure and VO2 in the perfused hindlimb of SHR and WKY.
NE-induced dose-response curves were constructed in the absence
(squares) or presence (circles) of 10 µM
dl-propranolol in both WKY (A and B) and SHR (C and D).
Basal values of perfusion pressure and VO2 are shown in
table 1. Data are means ± S.E. (n = 4).
P < .01 for the pressure curves in A and P > .05 for the
curve comparisons in B, C and D (ANOVA).
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Effects of 1-AR and
2-AR antagonists on NE-induced perfusion
pressure and VO2.
In WKY, both prazosin
(2.5 nM) and yohimbine (0.1 µM) markedly shifted NE-induced
dose-response curves of perfusion pressure and
VO2 to the right without changing
Pmax, VO2 max, or
VO2 min (fig. 3 A
and B; table 2). In SHR, the antagonistic effect of prazosin was much
bigger and that of yohimbine was significant only within the range of
LNE (fig. 3 C and D). NE-induced perfusion pressure was shifted to the
right more in SHR by prazosin compared with WKY and the differences in
associated changes in VO2 between SHR and WKY
disappeared (fig. 4). The
pKB values for prazosin and yohimbine of
NE-induced perfusion pressures for WKY were 9.24 and 7.34, respectively. In comparison, the pKB value
was higher for prazosin (9.81) and lower for yohimbine (6.89) in SHR.
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Fig. 3.
Effects of prazosin and yohimbine on NE-induced
perfusion pressure and VO2 in the perfused hindlimb of SHR
and WKY. Dose-response curves were constructed in the presence of 10 µM dl-propranolol. Basal values of perfusion pressure
and VO2 are shown in table 1. A and B represent WKY and C
and D represent SHR. Control (circles with solid lines), 2.5 nM
prazosin (squares with dash lines), 0.1 µM yohimbine (circles with
dash lines). Data are means ± S.E. (n = 4).
A, P < .01 for both prazosin and yohimbine; B, P < .01 for
prazosin in both sides, P < .01 for the ascending side and P > .05 for the descending side of yohimbine; C, P < .01 for
prazosin and P > .05 for yohimbine; D, P < .01 for prazosin
in both sides, P < .01 for the ascending side and P > .05 for the descending side of yohimbine Analyses were performed using
ANOVA (vs. control).
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Fig. 4.
Comparison of NE-induced perfusion pressure and
VO2 in the presence of prazosin or yohimbine in the
perfused hindlimb of SHR and WKY. The perfusions were performed in the
presence of 10 µM propranolol. Open symbols represent WKY and close
symbols represent SHR. 2.5 nM prazosin (A and B), 0.1 µM yohimbine (C
and D). Data are means ± S.E. (n = 4). A,
P = .056; B, P > .05; C, P < .01; D, P < .05 for
both sides (ANOVA).
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Effects of -1A-AR antagonists on NE-induced perfusion pressure
and VO2.
At 3.3 nM, 5 MU had no
significant effect on NE-induced changes in either pressure or
VO2 in WKY (fig. 5
A and B). In contrast, NE-induced dose-response curve of pressure was
shifted to the right by 5 MU more than 3-fold in SHR (fig. 5 C and D;
table 3) with a
pKB value of 8.94. Associated with the
inhibition of vasoconstriction, HNE-inhibited VO2
in SHR was markedly attenuated. Similar attenuation of HNE-inhibited
VO2 was also observed with KMD at 1 nM. However, the Pmax values were significantly reduced in
both WKY and SHR by KMD.
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Fig. 5.
Effect of -1A-antagonists on NE-induced
perfusion pressure and VO2 in the perfused hindlimb of SHR
and WKY. Dose-response curves were constructed in the presence of 10 µM dl-propranolol plus 0.1 µM yohimbine. Basal
values of perfusion pressure and VO2 are shown in table 1.
A and B represent WKY and C and D represent SHR. Control (circles with
dash lines), 3.3 nM 5 MU (hexagons with solid lines), 1 nM KMD (squares
with solid lines). Data are means ± S.E. (n = 4). A, P > .05 for 5 MU and P < .01 for KMD; B,
significance was only found for the descending side of KMD (P < .01); C, P < .01 for both 5 MU and KMD; D, P > .05 for the
ascending sides and P < .01 for the descending side of both 5 MU
and KMD. Analyses were performed using ANOVA (vs.
control).
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TABLE 3
Effect of 1-AR subtype antagonists on the pEC50 for
perfusion pressure and the pEC25 and pIC75 for
VO2 produced by NE in the perfused hindlimb of SHR and WKY
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Effects of -1D-AR antagonists on NE-induced perfusion pressure
and VO2.
Neither BMY (0.1 µM) nor SK&F
(2 µM) significantly altered NE-induced dose-response curves of
perfusion pressure in WKY (fig. 6 A and
B), although NE-induced perfusion pressure and the associated increases
in VO2 were both slightly reduced at 33 and 100 nM (P < .05). However, BMY and SK&F markedly shifted
dose-response curves of pressure to the right by 3.4- and 2.9-fold
respectively in SHR (table 3). Associated with the shift of the
pressure curve, LNE-elicited ascending limb of the
VO2 curve was markedly reduced and the
HNE-elicited descending limb was moderately attenuated (fig. 6 C and
D). Pretreatment with 10 µM CEC had only small inhibitory effect on
perfusion pressure and VO2 in SHR at one or two
low concentrations of NE without affecting the overall dose-response curves (P > .05, ANOVA). In WKY, pretreatment with 10 µM CEC
was without effect (data not shown).
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Fig. 6.
Effect of -1D-antagonists on NE-induced
perfusion pressure and VO2 in the perfused hindlimb of SHR
and WKY. Dose-response curves were constructed in the presence of 10 µM dl-propranolol plus 0.1 µM yohimbine. Basal
values of perfusion pressure and VO2 are shown in table 1.
A and B represent WKY and C and D represent SHR: control (circles with
dash lines), 0.1 µM BMY (triangles with solid lines) and 2 µM SK&F
(reversed triangles with solid lines). Data are means ± S.E.
(n = 4). A, P > .05 for BMY and SK&F; B,
P < .05 for the ascending side of both BMY and SK&F only; C,
P < .01 for both BMY and SK&F; D, P < .01 for the ascending
side of both BMY and SK&F and P < .05 for the descending side of
both BMY and SK&F. Analyses were performed using ANOVA
(vs. control).
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Because the effect of BMY or SK&F on HNE-inhibited
VO2 in SHR appeared similar to that of 5 MU, we
reduced the doses of BMY and SK&F by approximately 10-fold to avoid
possible cross action of BMY and SK&F at the -1A-AR subtype. The
results in figure 7 showed that 10 nM BMY
or 0.33 µM SK&F still significantly inhibited LNE-stimulated
VO2 but HNE-inhibited VO2
was not affected. Although not yet statistically different when
expressed using absolute units (mmHg), the fractional dose-response
curves (expressed as percentage of the maximum) with BMY and SK&F (data
not shown) were both significantly changed (P < .05, ANOVA). As a
result, the pEC50 values for pressure were
6.43 ± 0.02 for BMY and 6.41 ± 0.05 for SK&F, significantly
different from the control (6.62 ± 0.06, P < .05). The
pKB values were 7.73 and 6.33 for BMY and SK&F, respectively.
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Fig. 7.
Effects of low dose -1D-antagonists on
NE-induced perfusion pressure and VO2 in the perfused
hindlimb of SHR. Dose-response curves were constructed in the presence
of 10 µM dl-propranolol plus 0.1 µM yohimbine. Basal
values of perfusion pressure and VO2 were 44.2 ± 1.3 mmHg and 7.9 ± 0.1 µmol g
hr for BMY and 47.0 ± 1.1 mmHg and
7.4 ± 0.3 µmol g
hr for SK&F, respectively. Control (circles
with dash lines), 10 nM BMY (triangles) and 0.33 µM SK&F (reversed
triangles). Data are means ± S.E. (n = 4). A,
P > .05 for BMY and SK&F (however, when expressed as a fractional
change using percentage, P < .05 for the both; data not shown);
B, P < .01 for the ascending side of both BMY and SK&F, and
P > .05 for the descending side of both BMY and SK&F. Analyses
were performed using ANOVA (vs. control).
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Discussion |
Basal perfusion pressure and VO2.
SHR
have been shown to have a higher vascular resistance in skeletal muscle
in the absence (Cheng and Shibata, 1980) or presence (Adams et
al., 1989) of a vasodilator presumably due to morphological changes of the resistance vessels in muscle vascular bed. The increased
muscle vascular resistance in SHR was confirmed in the present
experiment. Interestingly, the basal VO2 of the
hindlimb was also found to be 13% higher in SHR. The reason for this
may be associated with increased numbers of the sarcolemmal
Na+-K+-ATP pump and its
overall compensatory activity to expel accumulated intracellular
Na+ at this age (Pickar et al., 1994).
Such an explanation is supported by recent findings showing an elevated
ATP turnover in skeletal muscle from patients with untreated primary
hypertension (Ronquist et al., 1995).
Roles of -ARs in altered vasoconstriction and
VO2 induced by NE in SHR.
-ARs have
been shown to be widely distributed in skeletal muscle of normal rats
in radioautography (Summers et al., 1995). We have
previously found blockade of
1/2-ARs by 1 µM
propranolol in perfused hindlimb of Wistar rats leads to a leftward
shift of vasoconstriction produced by adrenaline (Colquhoun et
al., 1990). Consistent with this earlier finding, blockade of
1/2-ARs by 10 µM
propranolol in our study also enhanced NE-induced vasoconstriction in
WKY with a small inhibition of VO2 max. In
comparison, propranolol did not show any significant effect on either
vasoconstriction or VO2 induced by NE in SHR,
pointing to a reduced role of -ARs in the muscle vascular bed.
Coincidentally, a loss of -AR-mediated vasodilation has been noted
in portal veins (Doggrell and Surman, 1995) and mesenteric arteries
(Blankesteijn et al., 1996) of SHR. Nonetheless, NE-induced
bell-shaped VO2 is not attributable to -ARs
because it was present in the presence of 10 µM propranolol.
Roles of 1- and
2-ARs in altered vasoconstriction and
VO2 induced by NE in SHR.
Compared with
-ARs, -ARs are sparse in skeletal muscle (Rattigan et
al., 1986) and predominantly located on small arteries with high
affinity for prazosin (Martin et al., 1990). In the constant-flow perfused hindlimb of Wistar rats performed earlier in
this laboratory, NE-induced biphasic changes in
VO2 were both completely reversed by prazosin at
concentrations more than 1000-fold lower than by yohimbine (Dora,
1993). In our study, the predominant role of -1-ARs in NE-induced
vasoconstriction and associated bell-shaped changes of
VO2 in the perfused rat hindlimb is supported by
a high pKB for prazosin (9.24) and low
pKB for yohimbine (7.34) in WKY. These
results are consistent with our recent findings that the -1-AR
agonist phenylephrine produces bell-shaped VO2 with a strong vasoconstriction whereas the -2-AR agonist UK-14,304 elicits only a small and monophasic increase in
VO2 with a much weaker vasoconstriction in the
perfused rat hindlimb (Hall et al., 1997). Compared with
WKY, -1-ARs in SHR are functionally up-regulated with decreases of
the role of -2-ARs in NE-induced changes in vasoconstriction as
suggested by a larger rightward shift of perfusion pressure by prazosin
at a lower dose in comparison to the effect of yohimbine. Subsequent
results showing antagonism by 5 MU, BMY and SK&F of NE-induced changes
in vasoconstriction and VO2 in SHR but not in WKY
in the presence of propranolol (10 µM) and yohimbine (0.1 µM)
further support this notion.
Roles of 1-AR subtypes in the altered
vasoconstriction and associated VO2 in
SHR.
The effects of -1A-AR subtype on NE-induced
vasoconstriction and descending limb of the VO2
curve were first suggested by a blockade by 5 MU at 0.25 µM in Wistar
rats (Dora, 1993). However, this dose appeared to be too high because
the Pmax at 20 µM of NE was only a quarter of
the control. In our study, 5 MU clearly showed antagonistic effects on
vasoconstriction in SHR without suppressing the
Pmax at 3.3 nM which had no effect in WKY. The pKB value of 8.94 is similar to those
reported for its action on the -1A-AR subtype in mesenteric, carotid
and caudal arteries of SHR (Villalobos-Molina and Ibarra, 1996).
Intriguingly, HNE-elicited descending limb of the
VO2 dose-response curve was markedly attenuated, but LNE-induced ascending limb of VO2 was
unaffected. Similar attenuating effects on HNE-elicited descending limb
of the VO2 curve were also found with 1 nM KMD.
These results suggest that HNE-elicited descending limb of the
bell-shaped VO2 dose-response curve appears to be
predominantly mediated by the 1A-AR subtype.
It was noted, however, that KMD did not differentiate NE-induced
vasoconstriction between SHR and WKY. The reason for this disparity
between these two -1A-antagonists at these doses tested is not
clear, but may be related to some other unknown properties of KMD. For
example, KMD has been shown to be a competitive -1A-antagonist in
human prostate and recombinant human and rat -1-ARs expressed in
Chinese hamster ovary cells (Shibata et al., 1995), whereas it showed an unsurmountable antagonism to NE-induced vasoconstriction in both WKY and SHR in our work. Pharmacological experiments in blood
vessels have suggested the presence of -1-AR subtypes with low
affinity for prazosin (the -1L and -1N) and 5 MU is known to have
low affinity for both -1L and -1N (Muramatsu et al., 1995). However, the effect of KMD, whose functionally high affinity for
-1-AR (a putative -1L-subtype) in human prostate has just been
identified (Moriyama et al., 1997), on the -1L and -1N subtypes in muscle vascular bed is yet to be clarified. Further studies
using other highly selective -1A-antagonists with low affinity for
the -1L-AR, such as the newly-developed RS 17053 (Ford et
al., 1996) may resolve this discrepancy.
BMY and SK&F are both -1D-subtype selective antagonists. The first
doses used for both BMY (0.1 µM) or SK&F (2 µM) clearly differentiate the differences between WKY and SHR. In the rat cremaster
vascular bed, BMY has been shown to be selective for the -1D-subtype
at this dose (Leech and Faber, 1996). The dose of SK&F is within the
range of its selectivity for the -1D-subtype (Hieble et
al., 1995b) and the influence of its higher affinity for all three
-2-AR subtypes was eliminated with the use of yohimbine. Neither BMY
nor SK&F caused any significant shift of the dose-pressure curve in
WKY, although a slight inhibition of both perfusion pressure and
VO2 was observed at very low concentrations of
NE. In contrast, both dose-response curves of perfusion pressure and
VO2 in SHR were markedly shifted to the right by
the same doses of either of these -1D-subtype antagonists. These
data suggest that the -1D-subtype is more likely to be functionally
up-regulated in the SHR hindlimb. In normal rats, -1B-ARs do not
contribute to arterial vasoconstriction in rat cremaster (Leech and
Faber, 1996) and perfused hindlimb (Zhu et al., 1997)
preparations. A small inhibition of 10 µM CEC of perfusion pressure
and VO2 in SHR at one or two low concentrations
of NE is consistent with its blocking action on the -1D-AR (Hieble
et al., 1995a).
Compared with the antagonistic effect of 5 MU, the most important
difference is that LNE-elicited ascending limb of the
VO2 dose-response curve was markedly decreased by
BMY and SK&F. Because HNE-elicited descending limb of the
VO2 curve in SHR hindlimb was similarly (although
moderately) attenuated by BMY and SK&F as to that by 5 MU, we reduced
the doses for these two -1D-subtype antagonists in the SHR hindlimb
to 10 nM and 0.33 µM, respectively. At these reduced doses, the
inhibitory effect of BMY and SK&F on LNE-elicited ascending limb of the
VO2 curve still remained but the their
attenuating effect on HNE-elicited descending limb of the
VO2 curve was diminished. Meanwhile, the
dose-response curve of perfusion pressure was slightly but
significantly shifted to the right. These data further support the
argument that the -1D-subtype is probably mainly responsible for
LNE-elicited increase in VO2 during
vasoconstriction in SHR muscle vascular bed and the -1A-AR for
HNE-elicited decreases in VO2. Experiments in other laboratories have revealed that NE has much higher affinity for
-1D-AR than for -1A-AR (Perez et al., 1994; Shibata
et al., 1995). Thus, the proposal that LNE increases
VO2 via the -1D-subtype while HNE decreases
VO2 via the -1A-subtype would be also in agreement with those findings by Perez et al. (1994) and
Shibata et al. (1995).
Mechanisms for -1-AR-mediated biphasic changes in
VO2.
The mechanism for -1-AR mediated
changes VO2 in muscle is not fully understood. As
previously reviewed by us (Clark et al., 1995 and references
therein), experiments using muscle preparations where nutrients are
delivered through diffusion, -1-AR agonists are unable to show any
marked stimulation of VO2. However, -1-AR agonists cause remarkable changes in VO2 via
-1-ARs in similar ways to other vasoconstrictors in the perfused rat
hindlimb where nutrients are delivered through the vascular system.
These vasoconstrictor-controlled changes in VO2
seem to be determined by the ratio of nutritive to nonnutritive routes
in the hindlimb presumably because of the heterogeneous distribution
and affinities of different receptors or receptor subtypes in the
vascular tree (Clark et al., 1995). For instance,
heterogeneous distribution of -1-AR subtypes has been shown in rat
skeletal muscle bed (Leech and Faber, 1996). In the context of the
present study, we speculate that the -1D-AR subtype may be
predominantly distributed on the precapillary arterioles before the
nonnutritive route, so that stimulation of this subtype may direct the
flow from nonnutritive to nutritive routes, leading to rises in
VO2. In contrast, the -1A-subtype may be
predominantly located in arterioles controlling nutritive routes and
stimulation of this subtype closes these nutritive routes, causing
functional vascular shunting. However, further experiments are needed
to reveal the distribution of -1A- and -1D-subtypes in relation to nutritive and nonnutritive routes in the microvascualture.
| |
Conclusion |
Two major findings have emerged from our study regarding
alterations of ARs in the SHR muscle vascular bed. First, the role of
-2- and -ARs in NE-elicited changes in vascular function and
VO2 in SHR muscle are impaired whereas the
effects of -1-ARs are markedly exacerbated. Second, both -1A- and
-1D-subtypes are functionally up-regulated in SHR muscle vascular
bed where increases in VO2 seem to be
predominantly mediated by the -1D- at a 100-fold lower concentration
of NE than decreases in VO2 which appear to be
predominantly mediated by the -1A-subtype. The results may provide
some clue for the possible role of -1-AR subtypes in the syndrome of
hypertension and obesity. If similar changes also occur in
vivo, the hypertension mediated by -1A-AR subtypes might be
more likely to be associated with obesity as they inhibit
thermogenesis. Hence, highly selective -1A-AR antagonists may offer
better control of obesity than other -1-AR antagonists during the
treatment of hypertension.
The authors thank Dr. K. A. Dora for her preliminary
experiments in hooded Wistar rats which contributed to initiating this study, Dr. C. Han for the discussion on use of selective
alpha-1 adrenoceptor subtype antagonists and Dr. S. Furler
for performing ANOVA analysis.
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Abstract
Introduction
