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Department of Physiology, West Virginia University School of Medicine, Morgantown, West Virginia 26505-9229
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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The purpose of this study was to determine if local nitric oxide (NO) activity attenuates the arteriolar myogenic response in rat spinotrapezius muscle. We also investigated the possibility that hypertension, dietary salt, or their combination can alter any influence of local NO on the myogenic response. Wistar-Kyoto rats (WKY) and spontaneously hypertensive rats (SHR) fed low-salt (0.45%, LS) or high-salt (7%, HS) diets were enclosed in a ventilated airtight box with the spinotrapezius muscle exteriorized for intravital microscopy. Mean arterial pressure was unaffected by dietary salt in WKY but was significantly higher and augmented by dietary salt in SHR. In all experiments, elevation of microvascular pressure by box pressurization caused a 0-30% decrease in the diameter of large (arcade bridge) arterioles and a 21-27% decrease in the diameter of intermediate (arcade) arterioles. Inhibition of NO synthase with NG-monomethyl-L-arginine (L-NMMA) significantly enhanced myogenic responsiveness of arcade bridge arterioles in WKY-LS and SHR-LS but not in WKY-HS and SHR-HS. L-NMMA significantly enhanced the myogenic responsiveness of arcade arterioles in all four groups. Excess L-arginine reversed this effect of L-NMMA in all cases, and arteriolar responsiveness to the NO donor sodium nitroprusside was not different among the four groups. High-salt intake had no effect on the passive distension of arterioles in either strain during box pressurization. We conclude that 1) local NO normally attenuates arteriolar myogenic responsiveness in WKY and SHR, 2) dietary salt impairs local NO activity in arcade bridge arterioles of both strains, and 3) passive arteriolar distensibility is not altered by a high-salt diet in either strain.
microcirculation; local blood flow control; hypertension
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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ARTERIOLAR MYOGENIC activity contributes significantly to local blood flow regulation in many vascular beds (12, 24, 35). The production of endothelium-derived relaxing factors represents another potentially important regulatory mechanism that is also intrinsic to the arteriolar wall (10, 21, 26). Although an intact endothelium is not required for the generation of myogenic activity in most vascular beds (13), endothelial factors such as nitric oxide (NO) have been shown to modulate the intensity of arteriolar myogenic activity in vitro (28, 46) and in vivo (10, 12, 24).
Spontaneous hypertension is characterized by an augmentation of arteriolar myogenic responsiveness in some vascular beds (14, 21, 22), but we have not found this to be the case in the spinotrapezius muscle of spontaneously hypertensive rats (SHR) (40). As with normotensive rats, inhibition of NO synthase (NOS) enhances the myogenic activity of renal afferent arterioles isolated from SHR, leading to a leftward shift of the pressure-diameter curve (20). To our knowledge, the importance of NO as a modulator of myogenic activity in vivo has not been evaluated for any vascular bed in SHR. If NO normally limits arteriolar myogenic activity in rat spinotrapezius muscle, then the absence of enhanced myogenic responsiveness in SHR spinotrapezius muscle could reflect a compensatory increase in local NO production and/or vascular smooth muscle responsiveness to NO. Alternatively, the production of some other endothelium-derived dilator or its effect on vascular smooth muscle could be increased under these conditions.
In normotensive rats, high dietary salt increases renal NO production (34), which could explain the reduced myogenic responsiveness of renal microvessels isolated from salt-fed rats (47). In contrast, we have reported that dietary salt reduces arteriolar NO activity in spinotrapezius muscle of normotensive rats (3, 5), which is consistent with a subsequent report in which endothelium-dependent dilation was impaired in gracilis muscle resistance arteries from Sprague-Dawley rats fed a high-salt diet (32). Although a salt-dependent suppression of microvascular NO activity should result in increased myogenic responsiveness, we have recently shown that arteriolar myogenic responses are attenuated in the spinotrapezius muscle of salt-fed Wistar-Kyoto rats (WKY) (40). This unexpected finding could be due to a difference between rat strains in the effect of dietary salt on local NO activity or to a lack of interaction between NO and myogenic behavior in this vascular bed.
In light of these unresolved issues, we undertook the current study to determine if local NO activity normally attenuates the arteriolar myogenic response in rat spinotrapezius muscle and to investigate the possibility that any such influence of NO could be changed by hypertension and/or dietary salt. Arteriolar responses to acute increases in transmural pressure were evaluated before and after local NOS inhibition in WKY and SHR fed low (0.45%, LS)- or high (7%, HS)-salt diets. Both large- and intermediate-sized arterioles were also studied to evaluate the possibility that segmental differences in NO activity exist in this vascular bed.
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METHODS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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All surgical and experimental procedures were approved by the West Virginia University Animal Care and Use Committee.
Animals. Male WKY and SHR (Harlan Sprague Dawley, Indianapolis, IN) were received at 4 wk of age and immediately placed on a whole grain, low-salt diet containing 0.45% NaCl (TD 88311, Tekland, Madison, WI). After 1 wk, half of the rats from each strain were randomly selected and placed on a high-salt diet containing 7% NaCl (TD 92100, Tekland), with the remaining rats continued on the low-salt diet. All rats were studied 4-5 wk after assignment to LS or HS groups.
Surgical preparation of the spinotrapezius muscle. Each rat was anesthetized with thiopental sodium (100 mg/kg ip) and placed on a heating pad to maintain a 37°C rectal temperature. The trachea was intubated to ensure a patent airway, and the right carotid artery was cannulated to measure arterial pressure. In some experiments, the right femoral vein was also cannulated to measure central venous pressure. The right spinotrapezius muscle was exteriorized for microscopic observation as previously described (40), leaving its innervation and all feed vessels completely intact. Throughout the surgery and subsequent experimental period, the muscle was continuously superfused with an electrolyte solution (in mM: 119 NaCl, 25 NaHCO3, 6 KCl, and 3.6 CaCl2) warmed to 35°C and equilibrated with 95% N2-5% CO2 (pH 7.35-7.40). Superfusate flow rate was maintained at 4-6 ml/min to minimize equilibration with atmospheric oxygen (40).
After the spinotrapezius muscle was surgically prepared, the rat was placed in an airtight, ventilated Plexiglas box (Fig. 1). The muscle was exteriorized from the box through a small slot and enclosed in a superfusate bath chamber. Fresh air was continuously circulated through the box, and box pressure (monitored with a mercury manometer and a Gould p23id pressure transducer) could be increased by raising the air inflow rate. Increases in box pressure cause simultaneous and equivalent increases in systemic arterial and venous pressure, leading to increased transmural pressures throughout the vasculature of the exteriorized tissue without changing heart rate, respiration rate, neurogenic vascular tone, or renin-angiotensin system activity (35). This technique has been used to study arteriolar myogenic responses in numerous vascular beds (35, 40).
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Intravital microscopy and measurement of microvascular variables. The animal preparation was transferred to the stage of an Olympus BHMJ intravital microscope (Hyde Park, NY) that was coupled to a charge-coupled device video camera (Dage-MTI, Michigan City, IN). Video images were displayed on a Sony high-resolution video monitor and videotaped for off-line analysis. Observations were made with an Olympus ×20 water-immersion objective (final video image magnification = ×1,460). Arteriolar red cell velocities were measured on-line with an optical Doppler velocimeter (Microcirculation Research Institute, Texas A&M University), and arteriolar inner diameters were measured during videotape replay with a video image-shearing monitor (IPM, San Diego, CA).
Branches of three different arteries enter the spinotrapezius muscle, where they connect to form an arteriolar structure known as the arcade bridge (45). The arcade bridge gives rise to a network of interconnected arcade arterioles that extends throughout the muscle. In the experiments described below, both arcade bridge and arcade arterioles were studied to identify any longitudinal differences in NO-dependent control that may exist in this portion of the network.Inhibition of NO synthesis.
To inhibit local NO synthesis, a stock solution of
NG-monomethyl-L-arginine
(L-NMMA) was continuously
infused by a syringe pump at 0.4 ml/min into the superfusate delivery
line. Stock L-NMMA concentration
was adjusted to produce a final superfusate concentration of
10
4 M. We have
previously found that L-NMMA at
this concentration maximally inhibits the dilation of spinotrapezius
muscle arterioles to ACh (5), an agonist that acts by increasing
endothelial NO production in this vascular bed (38). The specificity of L-NMMA as a NOS inhibitor was
verified in a separate series of control experiments
(experimental protocol 3).
Experimental protocol 1.
One to three arcade bridge or arcade arteriole segments were studied
per animal. After a 2-min control period, box pressure was raised to
10, 20, or 30 mmHg above atmospheric pressure for 2 min. We have
recently demonstrated that the arterial and venous pressure increases
evoked by box pressurization are completely transmitted to the
spinotrapezius muscle arterioles in each of the experimental groups
studied here (40). Box pressurization was followed by a minimum 2-min
recovery period to allow vessel diameter and red cell velocity to
return to control levels. This sequence was repeated a total of three
times for each selected arteriole to assess responsiveness to each of
the three pressure increases delivered in random order. To evaluate the
possible influence of endogenous NO on myogenic responsiveness, the
pressurization sequences were repeated for each vessel after 10 min of
exposure to L-NMMA. Continuous
superfusate delivery of L-NMMA
was maintained throughout all pressurization steps to maximally inhibit
NOS activity. At the end of every experiment, adenosine was added to
the superfusate at a final concentration of
104 M to determine the
passive diameter of each vessel that we studied.
Experimental protocol 2. To evaluate arteriolar responsiveness to NO in each experimental group, the NO donor sodium nitroprusside (SNP) was iontophoretically applied to individual arcade bridge arterioles. Glass micropipettes were beveled at a 23-25° angle to an outer tip diameter of 1-3 µm and filled with a 0.05 M solution of SNP in distilled water. The pipette tip was placed in light contact with the arteriolar wall, and a current programmer (model 260, World Precision Instruments, New Haven, CT) was used to deliver continuous 2-min ejection currents of 5, 10, and 20 nA. A recovery period of at least 2 min followed each application. The order of the 5- and 10-nA ejection currents was randomized, but the 20-nA ejection was always performed last because of a considerably slower recovery from this stimulus.
Experimental protocol 3. Because some L-arginine analogs could influence arteriolar tone via NO-independent mechanisms (27), we evaluated the specificity of L-NMMA as an inhibitor of NOS in arcade bridge and arcade arterioles of each experimental group. L-NMMA inhibits endothelial NO synthesis by competing with L-arginine for the binding site on the NOS enzyme (42) and by inhibiting L-arginine transport into the cell (6). Because both of these actions are reversed in the presence of excess L-arginine (6, 42), we reasoned that a reversal of the effect of L-NMMA on myogenic behavior by L-arginine would indicate a specific effect on the NO pathway.
With the use of the current experimental paradigm, the systemic pressure increases induced by higher levels of box pressurization are 20-30% lower in SHR than in WKY (40). Therefore, we compared responses to +20 mmHg box pressurization in WKY with responses to +30 mmHg box pressurization in SHR to evaluate L-NMMA specificity in the presence of an identical myogenic stimulus in all groups. Control, pressurization, and recovery periods (see Experimental protocol 1) were conducted first under the normal superfusate, then during L-NMMA exposure, and finally during simultaneous exposure to L-NMMA and excess L-arginine (5 × 103 M in superfusate).
Passive arcade bridge and arcade arteriole diameters were found to be
decreased in salt-fed rats of each strain (see
RESULTS). This effect could be due
to hypertrophy or remodeling of the arteriolar wall and/or a change in
its passive distensibility (8, 36). To gain some insight into the
passive mechanical characteristics of arterioles in each group, we
explored relative pressure-diameter relationships for passive arcade
bridge and arcade arterioles at the end of some experiments in
experimental protocols 1 and 3. After arteriolar tone was abolished
by 10 min of continuous exposure to adenosine
(104 M), arteriolar
diameter was measured at normal pressure and then after box pressure
was sequentially raised by 10, 20, and 30 mmHg. Each pressure step was
maintained for 1 min, and a recovery period followed the final step to
verify that vessels were not irreversibly damaged by passive
distension. Superfusion with adenosine was continued throughout these
procedures to ensure a sustained suppression of arteriolar tone.
Data and statistical analysis.
Arteriolar diameter (D, µm) and centerline red cell
velocity (Vcl,
mm/s) were sampled at 10-s intervals during all control, pressurization, and recovery periods. Resting vascular tone
(T) was calculated for each vessel
as follows: T = [(Dpass 
Dc)/Dpass] × 100, where
Dpass is passive
diameter under adenosine and
Dc is the
diameter measured during the control period. A tone of 100% represents
complete vessel closure, whereas 0% represents the passive state.
Arteriolar myogenic responses were evaluated by comparing the minimum
arteriolar diameter reached during box pressurization
(Dmin) to the
immediately preceding control diameter: D (% of control) = (Dmin/Dc) × 100. The effect of
L-NMMA on any myogenic response
was quantified as the difference between the normalized minimum
diameter reached during box pressurization under
L-NMMA and that reached during
box pressurization under the normal superfusate.
, nl/s) and
wall shear rate (WSR, s1)
as follows: = Vmean × (
× D2/4) and WSR = 8 × (Vmean/D).
WSR was used as an index of wall shear stress, and its calculation
assumes a parabolic velocity profile. Control values for all
microvascular variables were calculated as the mean of 12 samples
obtained during the 2-min control period.
All data are reported as means ± SE. Statistical analysis was
performed by commercially available software (SigmaStat, Jandel Scientific; Prism, Graphpad Software). Two-way repeated-measures ANOVA
was used to determine the effects of strain, diet, and strain-diet interactions on the measured variables. One-way ANOVA was used to
determine differences within a group subjected to repeated measures.
For all ANOVA procedures, the Student-Newman-Keuls method for post hoc
analysis was used to isolate pairwise differences among specific
groups. Analysis of covariance was used to determine differences in
regression line slopes. Significance was assessed at the 95%
confidence level (P < 0.05) for all tests.
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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General characteristics of all rats used in this study are reported in
Table 1. In both the WKY and SHR strains,
rats fed high salt were slightly but significantly older at the time of use than those fed low salt, but there were no significant differences in body weight among the four groups. Mean arterial pressure was significantly higher in SHR fed low salt than in WKY fed either low or
high salt. The high-salt diet significantly increased arterial pressure
in SHR but not in WKY.
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General characteristics of all arterioles studied are reported in Table
2. Arcade bridge arteriole resting
diameters were significantly smaller in SHR than in WKY. In contrast,
there was no strain-related difference in passive arcade bridge
diameters, reflecting a significant increase in the resting tone of SHR
arcade bridge arterioles. Arcade arteriole resting diameters were not different among the four experimental groups. The high-salt diet significantly reduced the passive diameters of both arcade bridge and
arcade arterioles in each strain.
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The effects of L-NMMA on resting
arteriolar diameters and hemodynamic variables are reported for each
group in Tables 3 and 4. At the arcade
bridge level (Table 3), resting volume flow was significantly lower in
SHR than in WKY, but there were no strain-related differences in
resting WSR. Exposure to L-NMMA did not alter resting arcade bridge diameter, tone, or volume flow in
any group. Resting arcade bridge WSR was reduced by
L-NMMA only in the WKY-LS group.
At the arcade arteriole level (Table 4),
there were no strain-related differences in resting flow or WSR, but
salt loading significantly reduced resting volume flow and WSR in both
strains. Exposure to L-NMMA did
not alter resting arcade arteriole diameter, tone, volume flow, or WSR
in any group.
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Upon box pressurization under the normal superfusate, arcade bridge
arterioles in each group displayed a moderate constriction or
maintained their normal resting diameter, indicating myogenic activation (Fig. 2). We have recently
reported that upon box pressurization to the levels used here, the
increase in arcade bridge pressure is identical to the increase in
arterial pressure (40). Therefore, the data in Fig. 2 are plotted as a
function of steady-state arterial pressure during each box
pressurization. This analysis reveals that myogenic responsiveness is
significantly enhanced by L-NMMA in the WKY-LS and SHR-LS groups only. For these two groups, the paired
pressure-diameter values for the normal and
L-NMMA superfusates are
significantly different at each level of increased pressure. In
addition, the slopes of the first-order regression lines fit to the
pressure-diameter data are significantly more negative in the presence
of L-NMMA. In contrast, arcade
bridge arterioles in the WKY-HS and SHR-HS groups did not display
augmented myogenic responsiveness during exposure to
L-NMMA. The line equations for each group are given in the legend of Fig. 2.
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At the arcade arteriole level, box pressurization under the normal
superfusate caused a similar degree of constriction in all experimental
groups (Fig. 3). These data are also
plotted as a function of steady-state arterial pressure during each box pressurization and indicate that arcade arteriole myogenic
responsiveness is enhanced by
L-NMMA in all groups. The paired
pressure-diameter values for the normal and
L-NMMA superfusates are
significantly different at the +20- and +30-mmHg pressure steps for
WKY-LS, WKY-HS, and SHR-LS and at +30 mmHg for SHR-HS. In addition, the slopes of the regression lines fit to the pressure-diameter data for
WKY-LS, WKY-HS, and SHR-HS are significantly more negative in the
presence of L-NMMA. The line
equations for each group are given in the legend of Fig. 3.
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Figure 4 compares the effect of
L-NMMA on the myogenic
responsiveness of arcade bridge vs. arcade arterioles in each group. In
WKY-LS and SHR-LS, the myogenic responses of arcade bridge and arcade
arterioles were similarly enhanced by
L-NMMA at all pressure steps,
except for a significantly greater effect in the arcade arterioles of
WKY-LS during the +30-mmHg pressure increase. In WKY-HS and SHR-HS,
L-NMMA consistently enhanced the
myogenic responsiveness of arcade arterioles only.
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Figure 5 displays the responsiveness of
arcade bridge arterioles to iontophoretically applied SNP in each
experimental group. The responses to SNP at each current dose represent
significant dilations from control diameter. There were no differences
among groups in the response to SNP at any current dose.
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Figure 6 illustrates the specificity of
L-NMMA under the conditions of
this study. As shown earlier,
L-NMMA significantly enhanced
the myogenic responsiveness of arcade bridge arterioles in WKY-LS and
SHR-LS. This effect was completely reversed when excess
L-arginine was added to the
superfusate (Fig. 6, top). As expected,
L-arginine had no effect on the
myogenic constriction of arcade bridge arterioles in WKY-HS and SHR-HS,
in which L-NMMA had no initial
effect. L-NMMA's enhancement of
myogenic responsiveness in arcade arterioles was completely reversed by
excess L-arginine in each group
(Fig. 6, bottom).
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After abolition of vascular tone, box pressurization caused the passive
distension of arcade bridge and arcade arterioles in each experimental
group (Fig. 7). Because microvascular
pressures were not directly measured in this study, true passive
pressure-diameter relationships could not be defined. However, we found
no differences among groups (for either vessel type) in the passive
diameter changes that occurred over a comparable range of arterial
pressure increases. After box pressure was returned to normal,
all arterioles regained their original passive diameter (data not
shown), indicating that they were not damaged by this distension.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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We present four major findings in this study. First, local NO activity normally attenuates the myogenic behavior of arcade bridge and arcade arterioles in spinotrapezius muscle of normotensive and hypertensive rats. Second, high dietary salt intake impairs this influence of local NO on arcade bridge arterioles. Third, high-salt intake, hypertension, or their combination does not alter arteriolar smooth muscle responsiveness to NO. Fourth, passive arteriolar distensibility is not altered in the spinotrapezius muscle of salt-loaded rats.
Resting microvascular characteristics associated with salt loading and hypertension. The distribution of cardiac output among different organs suggests that vascular resistance is uniformly increased throughout most of the peripheral circulation in SHR (39). However, the specific microvascular changes that are responsible for this increased resistance can vary markedly among different organs (7). The reduction in resting arcade bridge volume flow (Table 3) despite increased arterial perfusion pressure (Table 1) confirms that spinotrapezius muscle vascular resistance is increased in SHR, and this increase is due at least in part to the active reduction in resting arcade bridge diameters that we and others have observed (Table 3) (29, 40).
High-salt intake for 4-5 wk decreased passive arcade bridge and arcade arteriole diameters in both WKY and SHR (Table 2), indicating that these changes are unrelated to the level of arterial pressure. This effect has been previously reported in WKY and SHR (40) and in Dahl salt-sensitive and salt-resistant rats (4). A decrease in passive diameter could reflect hypotrophic, eutrophic, or hypertrophic remodeling of the arteriolar wall (36). Because circulating ANG II is required for the maintenance of normal arteriolar wall structure (48) and its plasma levels are reduced by salt loading (18), we would expect that if arteriolar wall remodeling had occurred in our salt-fed rats it would most likely be hypotrophic in nature. Consistent with this, hypotrophic remodeling of mesenteric arterioles has been morphometrically documented in normotensive Dahl salt-resistant rats fed a high-salt diet for 6-7 wk (30). Alternatively, it is possible that the salt-induced reduction in passive arteriolar diameter reflects a reduction in passive wall distensibility. High dietary salt has no effect on the passive distensibility of aortic segments from Sprague-Dawley or Dahl rats (1), but, to our knowledge, the effect of salt loading on passive distensibility has not been previously investigated at the microvascular level. A comparison of passive arteriolar responses to similar elevations in luminal pressure (Fig. 7) reveals that high dietary salt does not alter the passive pressure-diameter relationship over this modest pressure range in either WKY or SHR. Hypertension could also alter passive arteriolar distensibility in spinotrapezius muscle. The passive distensibility of pial arterioles in stroke-prone SHR is greater than that in WKY, apparently due to a disproportionate increase in more compliant elements of the arteriolar wall (2). In contrast, intestinal arterioles in SHR show a decreased passive distensibility compared with those in age-matched WKY (8). Finally, the passive pressure-diameter curves of mesenteric, coronary and cremaster muscle resistance vessels from SHR are not different from those of their normotensive counterparts (14, 17, 23). Although the slopes of the passive pressure-diameter curves for spinotrapezius muscle arterioles appear to be similar in WKY and SHR (Fig. 7), these data do not permit a definitive conclusion as to whether passive distensibility is altered in SHR spinotrapezius muscle because the arterioles in SHR were not studied over the same range of luminal pressure as those in WKY.Effect of local NO on arteriolar myogenic responses. To our knowledge, this is the first in vivo study to investigate the importance of local NO in modulating arteriolar myogenic behavior in normotensive, hypertensive, and salt-loaded rats. By using the "pressure-box" technique, transmural pressure was locally increased in a nonpharmacological manner, thereby avoiding any direct effect of an exogenous vasoactive agent on local NO activity. By limiting transmural pressure changes to vessels within the exteriorized muscle (35, 40), we also avoided activation of systemic baroreceptors and conduction of myogenic activity from vessels outside this vascular bed (44). We have recently reported that myogenic responses of spinotrapezius muscle arterioles are similar in SHR-LS and WKY-LS (40), which supports the growing consensus that myogenic activity is not uniformly increased in all vascular beds of the SHR (19, 23, 41).
Local NOS inhibition significantly enhanced the myogenic responsiveness of arcade bridge arterioles in WKY-LS and SHR-LS and in arcade arterioles from all four experimental groups (Figs. 2 and 3). This effect was completely reversed by excess L-arginine (Fig. 6), indicating that local NO normally attenuates the arteriolar myogenic response in spinotrapezius muscle of normotensive and hypertensive rats. Our findings are in agreement with recent work in the cremaster muscle of normotensive hamsters (10) and on the renal afferent arteriole of normotensive rabbits (25) and normotensive and hypertensive rats (20). NO also attenuates the constriction of arterioles in response to nonmyogenic stimuli, such as increased sympathetic nerve activity, in rat spinotrapezius muscle (31) and intestine (37). These studies clearly demonstrate that, despite the multiple origins of arteriolar tone, local NO activity plays an important role in determining the degree to which this tone is expressed. The shear stress associated with resting blood flow is considered to be the main stimulus for basal NO release from the endothelium of rat spinotrapezius muscle arterioles (16). We have recently reported that the myogenic constriction of these arterioles is accompanied by an increase in WSR (and therefore wall shear stress) (40), which should increase endothelial NO production (5, 16). Although the current findings indicate that local NO effectively limits the myogenic constriction of spinotrapezius muscle arterioles, we have previously found no correlation between WSR (either the resting value or its subsequent increase) and the magnitude of myogenic constriction (40). Together, these findings suggest that a second shear-independent stimulus may become responsible for the majority of NO released during myogenic constriction. The findings of Dora and co-workers (11) raise the intriguing possibility that the initial stretch-induced increase in vascular smooth muscle calcium could lead to the diffusion of calcium through myoendothelial junctions and into adjacent endothelial cells. This secondary increase in endothelial cell calcium could then stimulate increased NO production (33). Salt loading impaired the NO-dependent modulation of myogenic activity in arcade bridge arterioles of both WKY and SHR, as judged by unaltered myogenic responses in the presence of L-NMMA (Figs. 2 and 4). Because this salt-dependent impairment of local NO activity is similar to that previously reported in spinotrapezius muscle arterioles of Dahl salt-resistant rats (3, 5), it appears that this effect of dietary salt in normotensive rats is not strain specific. A more general effect of dietary salt on endothelial function is also suggested by earlier findings that rats fed high salt exhibit abnormally large cerebral infarctions after middle cerebral artery occlusion, apparently due to an impaired flow-dependent dilation of collateral vessels (9). We have recently reported that high dietary salt attenuates the myogenic responsiveness of arcade bridge arterioles in WKY spinotrapezius muscle (40). The current study indicates that this reduced responsiveness occurs despite a suppression of local NO activity (Fig. 2), suggesting that the effects of dietary salt on myogenic behavior and NO activity are independent and unrelated. Arcade bridge responsiveness to local application of the NO donor SNP was not different among experimental groups (Fig. 5), suggesting that the inherent responsiveness of arteriolar smooth muscle to NO is not altered in SHR or in salt-fed rats of either strain. These findings are consistent with observations on isolated arterioles from the SHR cremaster muscle (21) and previous in vivo observations in the spinotrapezius muscle of salt-loaded normotensive rats (5). Arteriolar responsiveness to NO has not been previously evaluated in salt-loaded SHR. Our finding that responsiveness to NO is not different between rat strains argues against the possibility that altered NO production in SHR could have been masked in this study by a compensatory change in smooth muscle responsiveness. Our finding that the attenuating influence of NO on myogenic constriction persists in SHR-LS, coupled with an unchanged arteriolar responsiveness to NO, strongly suggests that microvascular NO production is not suppressed in SHR, which is in agreement with previous studies (15, 20, 49). The current study does not allow us to identify the cellular origin of the NO that limits arteriolar myogenic responses in rat spinotrapezius muscle. As mentioned above, the microvascular endothelium is a likely source for this NO (3, 5). Skeletal muscle fibers can also produce NO (43), but NO released from these sites would have similar access to both arcade bridge and arcade arterioles and would therefore not be consistent with the differential effect of dietary salt on NO activity in these two vessel types (Figs. 2-4). This study provides further evidence that, in some vascular beds, local NO activity is suppressed by high dietary salt but unaltered by hypertension. Furthermore, salt-dependent alterations in NO activity and myogenic responsiveness appear to occur through distinctly separate mechanisms that warrant further investigation.| |
ACKNOWLEDGEMENTS |
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We gratefully acknowledge the expert technical assistance of Kim Wix.
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FOOTNOTES |
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This investigation was supported by National Heart, Lung, and Blood Institute Grants HL-44012 and HL-52019.
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: M. A. Boegehold, Dept. of Physiology, PO Box 9229, Robert C. Byrd Health Sciences Center, West Virginia Univ., Morgantown, WV 26506-9229 (E-mail: mboegehold{at}hsc.wvu.edu).
Received 19 January 1999; accepted in final form 22 June 1999.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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