| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Department of Physiology and Cardiovascular Research Center, Medical College of Wisconsin, Milwaukee, Wisconsin 53226
 |
ABSTRACT |
|---|
 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
This study examined the mechanism by
which cGMP contributes to the vasodilator response to nitric oxide (NO)
in rat middle cerebral arteries (MCA). Administration of a NO donor,
diethylaminodiazen-1-ium-1,2-dioate (DEA-NONOate), or 8-bromo-cGMP
(8-BrcGMP) increased the diameter of serotonin-preconstricted MCA by
79 ± 3%. The response to DEA-NONOate, but not 8-BrcGMP, was
attenuated by iberiotoxin (10
7 M) or a 80 mM
high-K+ media, suggesting that activation of K+
channels contributes to the vasodilator response to NO but not 8-BrcGMP. The effects of NO and cGMP on the vasoconstrictor response to
Ca2+ were also studied in MCA that were permeabilized with
-toxin and ionomycin. Elevations in bath Ca2+ from
108 to 105 M decreased the diameter of
permeabilized MCA by 76 ± 5%. DEA-NONOate (106 M)
and 8-BrcGMP (104 M) blunted this response by 60%.
Inhibition of guanylyl cyclase with
1H-[1,2,4]oxadiazole[4,3-a]
quinoxalin-1-one (105 M) blocked the inhibitory effect of
the NO donor, but not 8-BrcGMP, on Ca2+-induced
vasoconstriction. 8-BrcGMP (104 M) had no effect on
intracellular Ca2+ concentration
([Ca2+]i) in control, serotonin-stimulated,
or -toxin- and ionomycin-permeabilized vascular smooth muscle cells
isolated from the MCA. These results indicate that the vasodilator
response to NO in rat MCA is mediated by activation of
Ca2+-activated K+ channels via a
cGMP-independent pathway and that cGMP also contributes to the
vasodilator response to NO by decreasing the contractile response to
elevations in [Ca2+]i.
vascular smooth muscle; calcium sensitivity; cytochrome P-450
| |
INTRODUCTION |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
RECENT STUDIES
(6, 7, 36) have indicated that nitric oxide (NO) plays an
important role in the regulation of cerebral blood flow and mediates
the cerebral vascular responses to a wide variety of stimuli, including
acetylcholine (ACh), substance P, bradykinin, and
2-adrenergic receptor agonists. Inhibitors of NO
synthase constrict cerebral arteries in vitro and decrease cerebral
blood flow in vivo (10, 14, 27). There is also evidence
(10, 11) that impairment in NO-induced vasodilation plays
an important role in the pathogenesis of cerebral vasospasm.
Despite the importance of NO in the control of cerebral vascular tone,
its mechanism of action particularly in the middle cerebral artery
(MCA) of the rat remains to be fully defined. The results of previous
in vivo studies indicating that
1H-[1,2,4]oxadiazole[4,3-a] quinoxalin-1-one (ODQ), an inhibitor of guanylyl cyclase (GC), blocks
80% of the vasodilator response to ACh and NO in pial arteries of the
mouse, rat, and rabbit (4, 9, 28) and in the basilar artery of the rat (1, 29) in vivo support a primary role for cGMP in mediating the response to NO. The potential mechanisms by
which cGMP contributes to the vasodilator response to NO in vascular
smooth muscle (VSM) cells have been reviewed by Lincoln et al.
(16). They include activation of
Ca2+-sensitive K+ (KCa) channels
(15) and a reduction in intracellular Ca2+
concentration ([Ca2+]i) either by stimulation
of Ca2+ reuptake into intracellular Ca2+ stores
(37), blockade of Ca2+ influx
(23), and/or by inhibition of
D-myo-inositol 1,4,5-trisphosphate [Ins(1,4,5)P3]-mediated Ca2+ release
(26). In addition, cGMP has also been shown to desensitize the contractile mechanism to elevations of
[Ca2+]i in VSM (25). Many of
these mechanisms have been examined in the basilar artery of rabbits
(24), dogs (31), sheep (18), guinea pigs (35), and even rats (23).
However, few of these studies have examined multiple mechanisms in the
same vessel and none have been done in the MCA of the rat. This latter
point is potentially significant, because we (1, 33) and
other researchers (19, 20) have noted that the mechanisms
underlying the vasodilator response to NO appear to differ in the
basilar artery and MCA of the rat. The vasodilator response to NO is
completely cGMP dependent in the basilar artery of the rat (1,
29) and guinea pig (22) and is not affected by
KCa channel blockers (27). However, ~50% of
the response to NO in MCA of rats is cGMP independent and is secondary
to blockade of the formation of 20-hydroxyeicosatetraenoic acid
(20-HETE) and activation of KCa channels (1,
33). Furthermore, in patch-clamp studies, blockade of GC with
ODQ has no effect on the ability of NO to activate KCa
channels in MCA of rats (33). These findings suggest that
the vasodilator response to NO is mediated by different pathways in the
MCA and basilar arteries. Given the many mechanisms that may impact on
the vasodilator response to NO, and the fact that different pathways
seem to underlie the vasodilator response to NO in basilar arteries and
MCA of rats, it was therefore critical to determine the mechanisms that
contribute to the cGMP-dependent vasodilator response to NO in the MCA
of the rat. Therefore, the present study examined the following: 1) the contribution of K+ channels to the
vasodilator responses to NO and cGMP in MCA of the rat, 2)
the effects of NO and cGMP on intracellular Ca2+ levels in
VSM cells isolated from the MCA, and 3) the effects of NO
and cGMP on the vasoconstrictor response to increases in [Ca2+]i in MCA permeabilized with -toxin
and ionomycin.
| |
METHODS |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
Animals. Experiments were performed on 10- to 12-wk-old male Sprague-Dawley rats purchased from Harlan Sprague Dawley (Indianapolis, IN). The rats were housed in an Animal Care Facility at the Medical College of Wisconsin that is approved by the American Association for the Accreditation of Laboratory Animal Care. All protocols involving animals received approval by the Animal Care Committee of the Medical College of Wisconsin.
Isolated vessel studies. Rats were anesthetized with pentobarbital sodium (50 mg/kg ip), the brain was removed, and small branches of the MCA (inner diameter <100 µm) were microdissected. The MCA branches were then mounted on glass micropipettes under a microscope in a chamber filled with physiological saline solution (PSS) containing (in mM) 119 NaCl, 4.7 KCl, 1.17 MgSO4, 1.6 CaCl2, 12 NaHCO3, 1.18 NaH2PO4, 0.03 EDTA, 10 glucose, and 10 HEPES (pH 7.4). The bath was bubbled with a 95% O2-5% CO2 gas mixture and maintained at 37°C. The vessels were secured to the pipettes with 10-0 silk suture, and intraluminal pressure was maintained at 80 mmHg during the experiment. Vascular inner diameters were measured with a stereomicroscope, a charge-coupled device television camera (model KP-130AU, Hitachi), and video measurement system (model VIA-100, Boeckeler Instrument; Tucson, AZ).
Role of K+ channels in the vascular
responses to NO and cGMP.
The contribution of K+ channels to the vasodilator response
to NO and cGMP in rat MCA was assessed by comparing the response to
different concentrations of diethylaminodiazen-1-ium-1,2-dioate (DEA-NONOate; 109 to 105 M) and
8-bromo-cGMP (8-BrcGMP; 108 to 104 M) in
vessels preconstricted with serotonin (5-HT; 107 M) or a
depolarizing concentration of KCl (80 mM). The role that activation of
KCa channels plays in the vasodilator response was assessed
by comparing the response to DEA-NONOate or 8-BrcGMP before and after
addition of the KCa channel blocker iberiotoxin (IbTX)
(107 M) or a depolarizing concentration of K+
to the bath. The dose of IbTX used in the present study is based on
previous patch-clamp data (41) and functional data
(43), indicating that this concentration of IbTX
completely blocks KCa channels in VSM cells and isolated
perfused arterioles.
Effects of NO and cGMP on Ca2+
sensitivity in MCA.
These experiments were performed using MCA mounted in a vessel myograph
that were treated with -toxin (10 µg/ml) and ionomycin (105 M) to allow for equilibration of the
[Ca2+]i and extracellular
[Ca2+]. To eliminate the possibility that changes in bath
[Ca2+] might alter vascular tone by releasing endothelial
factors, the endothelium was first removed by perfusion of the vessels with PSS containing an antibody raised against the von Willebrand Factor (1:1,000 dilution) and guinea pig complement (2%) for 10 min,
followed by a 20-min wash with normal PSS (12).
Endothelial function was tested in each experiment by measuring the
vasodilator response to addition of ACh (103 M) to the
bath after preconstriction of the vessel with 5-HT (107
M). After being tested for functional removal of the endothelium, the
vessels were bathed with a low-Ca2+ (108 M)
cytoplasmic substitution solution (CSS) containing (in mM) 100 potassium propionate, 4 MgCl2, 20 piperazine-N,N'-bis(2-ethanesulfonic acid), 4 Na2ATP, 10 creatinine phosphate, 0.1 mg/ml creatinine phosphokinase, and 2 EGTA, pH 7.1. Staphylococcal -toxin (10 µg/ml) and ionomycin (105 M) were added to the bath to
permeabilize the vessel to Ca2+. After 30 min, the vessels
were washed with fresh low-Ca2+ CSS. The degree of
permeabilization was tested by comparison of the maximal
vasoconstrictor response to addition of Ca2+
(105 M) to the bath versus the vasoconstrictor response
to a depolarizing concentration of KCl (80 mM) before the vessels were
treated with ionomycin and -toxin.
7 to
105 M) were studied before and after the addition of
DEA-NONOate (106 M) or 8-BrcGMP (104 M) to
the bath. Other vessels were pretreated with the GC inhibitor ODQ
(105 M) to determine the role of cGMP in mediating the
inhibitory response of the NO donor on the vasoconstrictor response to
elevations in bath [Ca2+].
Study on [Ca2+]i in VSM cells. VSM cells were isolated from rat MCA by incubating the vessels in a low-Ca2+ Tyrode solution containing (in mM) 145 NaCl, 1 MgCl2, 4 KCl, 0.05 CaCl2, 10 glucose, and 10 HEPES (pH 7.4) with 1.5 mg/ml papain (14 U/mg), and 1 mg/ml dithiothreitol for 15 min at 37°C. The vessels were then spun down and transferred to a low-Ca2+ Tyrode solution composed of (in mg/ml) 0.5 elastase (90 U/ml), 1 soybean trypsin inhibitor (10,000 U/ml), and 2 collagenase (196 U/ml) for 20 min at 37°C. The supernatant was collected, and the cells were pelleted by centrifugation at 500 g for 1 min, resuspended in fresh low-Ca2+ Tyrode solution, and stored at 4°C.
[Ca2+]i were measured after loading the cells with 4 µM fura 2-acetoxymethyl ester (AM) in PSS containing 0.02% pluronic acid and 1 mg/ml albumin for 45 min at room temperature. After being loaded, the cells were transferred to a 1-ml perfusion chamber on an inverted microscope and superfused with PSS at 37°C for 30 min. [Ca2+]i was measured with the use of an imaging system (InCyt Im2, Intracellular Imaging; Cincinnati, OH) mounted on an inverted microscope (model IMT-2, Olympus Optical; Tokyo, Japan). The cells were visualized with the use of a ×40 ultraviolet fluorescence objective. The [Ca2+]i were calculated based on the fluorescence intensity ratios obtained using excitation and emission wavelengths of 340/380 and 510 nm and a standard curve generated using solutions with known [Ca2+].Effect of NO and cGMP on
[Ca2+]i in VSM cells
permeabilized with -toxin and ionomycin.
These experiments examined whether the inhibitory actions of cGMP and
NO on the vasoconstrictor response to Ca2+ in permeabilized
MCA were associated with changes in [Ca2+]i.
During the control period, the cells were bathed with a CSS solution
containing a Ca2+ concentration of 106 M, and
the [Ca2+]i response to DEA-NONOate
(106 M) or 8-BrcGMP (104 M) was studied.
The cells were then permeabilized with ionomycin (105 M)
and -toxin (10 µg/ml), and the experiment was repeated.
Effect of NO and cGMP on [Ca2+]i in VSM
cells stimulated with 5-HT.
These experiments examined whether cGMP and NO alter
[Ca2+]i in VSM cells isolated from the MCA of
the rat after stimulation with 5-HT.
[Ca2+]i were measured under
control condition and after 5-HT (105 M) was added to the
bath. 5-HT produced a transient increase in
[Ca2+]i, followed by a steady-state increase.
After [Ca2+]i reached a stable plateau value,
DEA-NONOate (106 M) or 8-BrcGMP (104 M) was
added to the bath and changes in [Ca2+]i were
monitored for an additional 10 min.
Role of KCa channels in the change in
[Ca2+]i induced by NO in
5-HT-stimulated VSM cells.
Because DEA-NONOate decreased [Ca2+]i in VSM
cells stimulated with 5-HT, the contribution of activation of
KCa channels to the fall in
[Ca2+]i produced by NO was examined. In this
experiment, IbTX (107 M), a selective KCa
channel blocker, was added to the bath before administration of 5-HT
and DEA-NONOate.
Drugs and chemicals. All chemicals were of analytic grade. Collagenase type II was purchased from Worthington (Freehold, NJ). DEA-NONOate and 8-BrcGMP were purchased from Calbiochem (La Jolla, CA), ODQ was obtained from Alexis (San Diego, CA), ionomycin was from Biomol (Plymouth Meeting, PA), and fura 2-AM and pluronic acid were purchased from Molecular Probes (Eugene, OR). All other chemicals used in this study were purchased from Sigma (St. Louis, MO).
Statistics. Values are presented as means ± SE. The significance of differences in mean values between and within groups in the isolated vessel studies was examined using analysis of variance for repeated measurements, followed by the Duncan's multiple-range test. A paired t-test was used to examine the significance of differences in [Ca2+]i in the studies using isolated VSM cells. P < 0.05 was considered to be significant.
| |
RESULTS |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
Role of K+ channels in the
vasodilator response to NO and cGMP.
Under control conditions, DEA-NONOate (109 to
105 M) dose dependently dilated MCA preconstricted with
5-HT (107 M) to 79 ± 4% of control (Fig.
1). Preconstricting the vessels with a
depolarizing concentration of KCl (80 mM) or addition of the selective
KCa channel blocker IbTX (107 M) to the bath
significantly impaired the vasodilator response to the NO donor by 50%
(Fig. 1A). In contrast, blocking K+ channel
activity with 80 mM KCl or IbTX had little effect on the vasodilator
response to 8-BrcGMP (104 M) (Fig. 1B).
|
Effect of NO and cGMP on the vasoconstrictor response to
Ca2+ in MCA permeabilized with -toxin
and ionomycin.
Baseline diameter of the MCA used in these studies averaged 110 ± 4 µm. The diameter of these vessels fell to 51 ± 3 µm after addition of 5-HT to the bath and rose to 108 ± 5 µm after the administration of ACh. Removal of the endothelium markedly impaired the
vasodilator response to ACh. Vessel diameters averaged 109 ± 4, 50 ± 1, and 52 ± 4 µm, respectively, before and after the addition of 5-HT and ACh to the bath. The control vasoconstrictor responses to elevations in bath [Ca2+] in
deendothelialized MCA subsequently treated with DEA-NONOate or
8-Br-cGMP were similar. Therefore, the results from these two groups
were pooled and presented together in Fig.
2. Under control conditions, an elevation
in bath [Ca2+], from 108 to
105 M, reduced the diameter of the MCA by 76 ± 5%.
DEA-NONOate (106 M) had no significant effect on the
baseline diameter of permeabilized MCA measured at a bath
[Ca2+] of 108 M (136 ± 17 vs.
135 ± 17 µm before and after DEA-NONOate, respectively). However, it did reduce the vasoconstrictor response to an elevation in
bath [Ca2+] to 105 M by 55%. Similarly,
8-BrcGMP (104 M) had no significant effect on the
baseline diameter of permeabilized MCA, but it also reduced the
vasoconstrictor response to the elevation in bath [Ca2+]
to 105 M by 60%. The inhibitory effect of DEA-NONOate on
the vasoconstrictor response to changes in bath [Ca2+]
was completely blocked by addition of the GC inhibitor ODQ
(105 M) to the bath.
|
Effect of NO and cGMP on
[Ca2+]i in VSM cells
permeabilized with -toxin and ionomycin.
The results of these experiments are presented in Figs.
3 and 4. Under control conditions (Fig.
3A), DEA-NONOate (106 M) had no significant
effect on [Ca2+]i in VSM cells isolated from
MCA of rats. Mean [Ca2+]i averaged 98 ± 11 nM before and 88 ± 7 nM 2 min after the addition of
DEA-NONOate to the bath. [Ca2+]i increased
rapidly from 88 ± 11 nM to 1,580 ± 211 nM after
permeabilizing the cells with ionomycin (105 M) and
-toxin (10 µg/ml) in a CSS solution with a 105 M
free [Ca2+] (Fig. 3B). DEA-NONOate
(106 M) had no significant effect on
[Ca2+]i under these experimental conditions.
Similarly, 8-BrcGMP (104 M) had no significant effect on
[Ca2+]i in the VSM cells before (72 ± 7 vs. 67 ± 7 nM; Fig. 4A)
or after (1,047 ± 98 vs. 1,043 ± 99 nM; Fig. 4B)
the cells were permeabilized with ionomycin and -toxin. To exclude
the possibility that the lack of effects of DEA-NONOate and
8- BrcGMP on [Ca2+]i was due to an
inability of our system to detect decreases in [Ca2+]i, the cells were also treated with
EDTA (10 mM). As shown in Fig. 4B, the addition of EDTA to
the bath markedly reduced [Ca2+]i in the
permeabilized VSM cells to values close to 0 nM.
|
|
Effect of NO and cGMP on
[Ca2+]i in VSM cells
stimulated with 5-HT.
The results of these experiments are presented in Figs.
5 and 6. Stimulation of the VSM cells
with 5-HT produced a transit increase in
[Ca2+]i from 90 ± 7 to 211 ± 27 nM, followed by a sustained plateau phase, in which
[Ca2+]i remained ~15% above control (Figs.
5 and 6). Addition of 8- BrcGMP to the bath during the plateau phase
had no significant effect on [Ca2+]i in VSM
cells isolated from the MCA that were stimulated with 5-HT (Fig. 5). In
contrast, the NO donor DEA-NONOate reduced
[Ca2+]i by 16 ± 1% (Fig.
6). Pretreatment of the cells with IbTX
potentiated the steady-state rise in [Ca2+]i
produced by 5-HT from 11 ± 2 to 20 ± 3% above control
(Fig. 6). Furthermore, blockade of KCa channels also
significantly reduced the fall in [Ca2+]i
from 16 ± 1 to 11 ± 1% after administration of DEA-NONOate to the bath (Fig. 6).
|
|
| |
DISCUSSION |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
Previous studies (5, 17, 39) have indicated that the vasodilator response to NO is mediated by cGMP-dependent and -independent pathways (3, 8). In renal arterioles (32) and MCA (17, 19, 33) of the dog and rat, activation of KCa channels has been previously reported to contribute ~50% to the vasodilator response to NO. The increase in KCa channel activity appears to be mediated by inhibition of the formation of 20-HETE, rather than to an elevation in cGMP levels, because preventing the NO-induced fall in 20-HETE levels by adding it to the bath abolishes the ability of a NO donor to activate KCa channels and attenuates the vasodilator response in rat renal arterioles and MCA (32, 33). In addition, blockade of GC with ODQ has no effect on the activation of K+ channels produced by NO in VSM cells isolated from rat renal arterioles and MCA (32, 33). Nevertheless, ODQ still reduces the vasodilator response to NO by 50% in rat renal and cerebral arteries (1, 17, 33). However, the vasodilator response to NO in basilar arteries of the rat (1, 29) and guinea pig (22) can be completely blocked by inhibition of GC. These observations suggest that the pathways underlying the vasodilator response to NO are different in the basilar artery and MCA and that cGMP contributes to the vasodilator response to NO in rat MCA via a mechanism that is independent of activation of KCa channels.
In the present study, we first confirmed that blockade of K+ channels with a depolarizing concentration of KCl (80 mM) or KCa channels with IbTX decreased the vasodilator response to NO by 50% in rat MCA under the present experimental conditions (Fig. 1). This observation fits with previous results, indicating that activation of K+ channels secondary to inhibition of the formation of 20-HETE contributes ~50% to the vasodilator response to NO in the MCA of the rat (1, 33). These results are also consistent with the results of other studies demonstrating that activation of KCa channels contributes to the vasodilator response to NO in other vascular beds, including cerebral arteries studied in vitro (2, 3, 17, 21, 24, 32, 33). However, it is important to recognize that there is not unequivocal support for a role for KCa channels in mediating the response to NO. Indeed, studies in rat MCA (33), basilar arteries (29), pulmonary arteries (42), and bovine coronary arteries (15) have indicated that NO activates 4-aminopyridine-sensitive K+ channels. Blockade of KCa channels with IbTX had little effect on the vasodilator response to NO and ACh in pial arteries of rabbits (34) or the basilar artery of the rat (27) studied in vivo. The vasodilator responses to sodium nitroprusside, 8-BrcGMP and ACh in these studies were attenuated by the blockade of voltage-sensitive K+ (Kv) channels with 4-aminopyridine. These studies indicate that in some vessels, activation of Kv channels contributes to the vasodilator response to NO, whereas in others, it involves activation of KCa channels. The reason for the differences in these results remains to be determined but may reflect species differences or differences in the types or density of K+ channels expressed in VSM cells in different vessels.
In contrast to what was observed after administration of the NO donor
in the present study, the vasodilator response to 8-BrcGMP in MCA was
not affected by blockade of KCa channels with IbTX (107 M) or by the addition of a depolarizing
concentration of K+ to the bath. These observations are
consistent with previous patch-clamp data (33), indicating
that blockade of GC with ODQ does not alter the NO-induced activation
of K+ channels in VSM cells isolated from rat MCA. Thus
cGMP must contribute to the vasodilator response to NO in the MCA of
the rat by some other mechanism. To evaluate this hypothesis further,
we compared the effects of DEA-NONOate and 8-BrcGMP on the
vasoconstrictor response to elevations in bath Ca2+ in MCA
permeabilized with ionomycin and -toxin. We found that the NO donor
DEA-NONOate (106 M) produced a rightward shift of the
concentration-constriction curve for Ca2+ (Fig. 2). In
addition, the inhibitory effect of DEA-NONOate on Ca2+-induced vasoconstriction was not associated with a
change in [Ca2+]i in VSM cells isolated from
the MCA of rats that were permeabilized with ionomycin and -toxin
(Fig. 3). These findings suggest that the effect of NO to reduce the
vasoconstrictor response to Ca2+ in permeabilized rat MCA
is not mediated by a reduction in [Ca2+]i,
but rather is due to a decrease in the contractile response to an
elevation in [Ca2+]i. The effects of NO on
the vasoconstrictor response to Ca2+ were completely
blocked by ODQ (Fig. 2), indicating that this effect is cGMP dependent.
We also found that 8-BrcGMP mimicked the response to NO in
permeabilized rat MCA and decreased the vasoconstrictor response to
elevations in [Ca2+]i (Fig. 2). 8-BrcGMP also
failed to change [Ca2+]i in MCA VSM cells
permeabilized with ionomycin and -toxin (Fig. 4). Moreover, 8-BrcGMP
had no effect on [Ca2+]i in VSM cells
isolated from the MCA when studied under control condition or after the
cells were stimulated with 5-HT (Fig. 5). These results indicate that
cGMP-induced attenuation of the vasoconstrictor response to elevated
[Ca2+]i in permeabilized MCA is not mediated
by a decrease in [Ca2+]i, but rather by a
decrease in the contractile response to an elevation in
[Ca2+]i. In contrast to the results obtained
with cGMP, we found that addition of the NO donor significantly reduced
[Ca2+]i in VSM cells stimulated with 5-HT
(Fig. 6) and the decrease in [Ca2+]i was
attenuated, but not eliminated, by blockade of KCa channels with IbTX (Fig. 6). These findings are consistent with the view that
NO-induced activation of KCa channels contributes to the fall in [Ca2+]i by hyperpolarizing the cell
membrane and reducing Ca2+ influx through voltage-gated
Ca2+ channels (23). They also indicate that
other mechanisms contribute to the decrease in
[Ca2+]i produced by NO in these vessels,
because blockade of KCa channels did not completely block
the NO-induced fall in [Ca2+]i. These
mechanisms include activation of other type of K+ channels
(29, 33, 34) and/or stimulation of Ca2+
reuptake into intracellular stores as reported by Twort and van Breemen
(37).
The mechanism by which cGMP decreases the vasoconstrictor response to elevations in [Ca2+]i in the rat MCA remains to be determined. Contraction of VSM is dependent on the phosphorylation and dephosphorylation of the myosin light chain protein (30). Phosphorylation of the myosin light chain is mediated by Ca2+-calmodulin activated myosin light-chain kinase, and dephosphorylation depends on myosin light chain phosphatase. Thus a decrease of the activity of Ca2+-calmodulin activated myosin light-chain kinase and/or an increase in the activity of myosin light chain phosphatase could contribute to the decrease in the contractile response to an elevation of [Ca2+]i. Indeed, several investigators (13, 25, 38, 40) have reported that cGMP activates protein kinases that phosphorylate and modify the activity of both of these enzymes. Thus it is likely that both mechanisms contribute to the cGMP-induced fall in the vasoconstrictor response to elevations in [Ca2+]i in rat MCA.
In summary, the present results indicate that the vasodilator response to NO in the MCA of the rat is mediated by activation of KCa channels (cGMP independent) and cGMP-dependent pathways and the cGMP-dependent pathway is mediated by an effect of cGMP to decrease the contractile response to elevations in [Ca2+]i, rather than by activation of K+ channels or a fall in [Ca2+]i.
| |
ACKNOWLEDGEMENTS |
|---|
This work was supported in part by National Heart, Lung, and Blood Institute Grants HL-59996, HL-29587, and HL-10407.
| |
FOOTNOTES |
|---|
Address for reprint requests and other correspondence: R. J. Roman, Dept. of Physiology, Medical College of Wisconsin, 8701 Watertown Plank Rd., Milwaukee, WI 53226 (E-mail: rroman{at}mcw.edu).
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. Section 1734 solely to indicate this fact.
First published January 10, 2002;10.1152/ajpheart.00699.2001
Received 6 August 2001; accepted in final form 3 January 2002.
| |
REFERENCES |
|---|
|
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
|
|---|
1.
Alonso-Galicia, M,
Hudetz AG,
Shen H,
Harder DR,
and
Roman RJ.
Contribution of 20-HETE to vasodilator actions of nitric oxide in the cerebral microcirculation.
Stroke
30:
2727-2734,
1999.
2.
Alvarez, J,
Montero M,
and
Garcia-Sancho J.
High affinity inhibition of Ca2+-dependent K+ channels by cytochrome P-450 inhibitors.
J Biol Chem
267:
11789-11793,
1992.
3.
Archer, SL,
Huang JM,
Hampl V,
Nelson DP,
Shultz PJ,
and
Weir EK.
Nitric oxide and cGMP cause vasorelaxation by activation of a charybdotoxin-sensitive K channel by cGMP-dependent protein kinase.
Proc Natl Acad Sci USA
91:
7583-7587,
1994.
4.
Baughman, VL,
Wang Q,
and
Pelligrino DA.
Oxadiaxoloquinoxalinone (ODQ) is an effective blocker of soluble guanylate cyclase (sGC) in rat pial arterioles in vivo (Abstract).
FASEB J
11:
A246,
1997.
5.
Bolotina, VM,
Najibi S,
Palacino JJ,
Pagano PJ,
and
Cohen RA.
Nitric oxide directly activates calcium-dependent potassium channels in vascular smooth muscle.
Nature
368:
850-853,
1994.
6.
Brian, JE, Jr,
Faraci FM,
and
Heistad DD.
Recent insights into the regulation of cerebral circulation.
Clin Exp Pharmacol Physiol
23:
449-457,
1996.
7.
Bryan, RM, Jr,
Steenberg ML,
Eichler MY,
Johnson TD,
Swafford MW,
and
Suresh MS.
Permissive role of NO in 2-adrenoceptor-mediated dilations in rat cerebral arteries.
Am J Physiol Heart Circ Physiol
269:
H1171-H1174,
1995.
8.
Cohen, RA,
and
Vanhoutte PM.
Endothelium-dependent hyperpolarization. Beyond nitric oxide and cyclic GMP.
Circulation
92:
3337-3349,
1995.
9.
Faraci, FM,
and
Sobey CG.
Role of soluble guanylate cyclase in dilator responses of the cerebral microcirculation.
Brain Res
821:
368-373,
1999.
10.
Iadecola, C,
Pelligrino DA,
Moskowitz MA,
and
Lassen NA.
Nitric oxide synthase inhibition and cerebrovascular regulation.
J Cereb Blood Flow Metab
14:
175-192,
1994.
11.
Ito, Y,
Isotani E,
Mizuno Y,
Azuma H,
and
Hirakawa K.
Effective improvement of the cerebral vasospasm after subarachnoid hemorrhage with low-dose nitroglycerin.
J Cardiovasc Pharmacol
35:
45-50,
2000.
12.
Juncos, LA,
Ito S,
Carretero OA,
and
Garvin JL.
Removal of endothelium-dependent relaxation by antibody and complement in afferent arterioles.
Hypertension
23:
I54-I59,
1994.
13.
Kawada, T,
Toyosato A,
Islam MO,
Yoshida Y,
and
Imai S.
cGMP-kinase mediates cGMP- and cAMP-induced Ca2+ desensitization of skinned rat artery.
Eur J Pharmacol
323:
75-82,
1997.
14.
Kontos, HA.
Nitric oxide and nitrosothiols in cerebrovascular and neuronal regulation.
Stroke
24:
I155-I158,
1993.
15.
Li, PL,
Jin MW,
and
Campbell WB.
Effect of selective inhibition of soluble guanylyl cyclase on the KCa channel activity in coronary artery smooth muscle.
Hypertension
31:
303-308,
1998.
16.
Lincoln, TM,
Dey N,
and
Sellak H.
cGMP-dependent protein kinase signaling mechanisms in smooth muscle: from the regulation of tone to gene expression.
J Appl Physiol
91:
1421-1430,
2001.
17.
Marshall, JJ,
Wei EP,
and
Kontos HA.
Independent blockade of cerebral vasodilation from acetylcholine and nitric oxide.
Am J Physiol Heart Circ Physiol
255:
H847-H854,
1988.
18.
Nauli, SM,
Zhang L,
and
Pearce WJ.
Maturation depresses cGMP-mediated decreases in [Ca2+]i and Ca2+ sensitivity in ovine cranial arteries.
Am J Physiol Heart Circ Physiol
280:
H1019-H1028,
2001.
19.
Onoue, H,
and
Katusic ZS.
Role of potassium channels in relaxations of canine middle cerebral arteries induced by nitric oxide donors.
Stroke
28:
1264-1270,
1997.
20.
Onoue, H,
and
Katusic ZS.
The effect of 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (ODQ) and charybdotoxin (CTX) on relaxations of isolated cerebral arteries to nitric oxide.
Brain Res
785:
107-113,
1998.
21.
Peng, W,
Hoidal JR,
and
Farrukh IS.
Regulation of Ca2+-activated K+ channels in pulmonary vascular smooth muscle cells: role of nitric oxide.
J Appl Physiol
81:
1264-1272,
1996.
22.
Petersson, J,
Zygmunt PM,
Jonsson P,
and
Hogestatt ED.
Characterization of endothelium-dependent relaxation in guinea pig basilar artery-effect of hypoxia and role of cytochrome P450 mono-oxygenase.
J Vasc Res
35:
285-294,
1998.
23.
Porter, VA,
Bonev AD,
Knot HJ,
Heppner TJ,
Stevenson AS,
Kleppisch T,
Lederer WJ,
and
Nelson MT.
Frequency modulation of Ca2+ sparks is involved in regulation of arterial diameter by cyclic nucleotides.
Am J Physiol Cell Physiol
274:
C1346-C1355,
1998.
24.
Robertson, BE,
Schubert R,
Hescheler J,
and
Nelson MT.
cGMP-dependent protein kinase activates Ca-activated K+ channels in cerebral artery smooth muscle cells.
Am J Physiol Cell Physiol
265:
C299-C303,
1993.
25.
Sauzeau, V,
Le Jeune H,
Cario-Toumaniantz C,
Smolenski A,
Lohmann SM,
Bertoglio J,
Chardin P,
Pacaud P,
and
Loirand G.
Cyclic GMP-dependent protein kinase signaling pathway inhibits RhoA-induced Ca2+ sensitization of contraction in vascular smooth muscle.
J Biol Chem
275:
21722-21729,
2000.
26.
Schlossmann, J,
Ammendola A,
Ashman K,
Zong X,
Huber A,
Neubauer G,
Wang GX,
Allescher HD,
Korth M,
Wilm M,
Hofmann F,
and
Ruth P.
Regulation of intracellular calcium by a signalling complex of IRAG, IP3 receptor and cGMP kinase I
.
Nature
404:
197-201,
2000.
27.
Sobey, CG,
and
Faraci FM.
Effect of nitric oxide and potassium channel agonists and inhibitors on basilar artery diameter.
Am J Physiol Heart Circ Physiol
272:
H256-H262,
1997.
28.
Sobey, CG,
and
Faraci FM.
Effects of a novel inhibitor of guanylyl cyclase on dilator responses of mouse cerebral arterioles.
Stroke
28:
837-842,
1997.
29.
Sobey, CG,
and
Faraci FM.
Inhibitory effect of 4-aminopyridine on responses of the basilar artery to nitric oxide.
Br J Pharmacol
126:
1437-1443,
1999.
30.
Somlyo, AP,
Wu X,
Walker LA,
and
Somlyo AV.
Pharmacomechanical coupling: the role of calcium, G-proteins, kinases and phosphatases.
Rev Physiol Biochem Pharmacol
134:
201-234,
1999.
31.
Sugawa, M,
Tamura K,
Koide T,
and
Naitoh S.
Functional roles of cyclic guanosine 3',5'-monophosphate analogue in cerebral vasodilation.
Gen Pharmacol
24:
577-584,
1993.
32.
Sun, CW,
Alonso-Galicia M,
Taheri MR,
Falck JR,
Harder DR,
and
Roman RJ.
Nitric oxide-20-hydroxyeicosatetraenoic acid interaction in the regulation of K+ channel activity and vascular tone in renal arterioles.
Circ Res
83:
1069-1079,
1998.
33.
Sun, CW,
Falck JR,
Okamoto H,
Harder DR,
and
Roman RJ.
Role of cGMP versus 20-HETE in the vasodilator response to nitric oxide in rat cerebral arteries.
Am J Physiol Heart Circ Physiol
279:
H339-H350,
2000.
34.
Taguchi, H,
Heistad DD,
Kitazono T,
and
Faraci FM.
Dilatation of cerebral arterioles in response to activation of adenylate cyclase is dependent on activation of Ca2+-dependent K+ channels.
Circ Res
76:
1057-1062,
1995.
35.
Tewari, K,
and
Simard JM.
Sodium nitroprusside and cGMP decrease Ca2+ channel availability in basilar artery smooth muscle cells.
Pflügers Arch
433:
304-311,
1997.
36.
Toda, N,
and
Okamura T.
Nitroxidergic nerve: regulation of vascular tone and blood flow in the brain.
J Hypertens
14:
423-434,
1996.
37.
Twort, CH,
and
van Breemen C.
Cyclic guanosine monophosphate-enhanced sequestration of Ca2+ by sarcoplasmic reticulum in vascular smooth muscle.
Circ Res
62:
961-964,
1988.
38.
Van Riper, DA,
McDaniel NL,
and
Rembold CM.
Myosin light chain kinase phosphorylation in nitrovasodilator induced swine carotid artery relaxation.
Biochim Biophys Acta
1355:
323-330,
1997.
39.
Weisbrod, RM,
Griswold MC,
Yaghoubi M,
Komalavilas P,
Lincoln TM,
and
Cohen RA.
Evidence that additional mechanisms to cyclic GMP mediate the decrease in intracellular calcium and relaxation of rabbit aortic smooth muscle to nitric oxide.
Br J Pharmacol
125:
1695-1707,
1998.
40.
Wu, X,
Somlyo AV,
and
Somlyo AP.
Cyclic GMP-dependent stimulation reverses G-protein-coupled inhibition of smooth muscle myosin light chain phosphate.
Biochem Biophys Res Commun
220:
658-663,
1996.
41.
Zhang, H,
Li P,
Almassi GH,
Nicolosi A,
Olinger GN,
and
Rusch NJ.
Single-channel and functional characteristics of a KCa channel in vascular muscle membranes of human saphenous veins.
J Cardiovasc Pharmacol
28:
611-617,
1996.
42.
Zhao, YJ,
Wang J,
Rubin LJ,
and
Yuan XJ.
Inhibition of KV and KCa channels antagonizes NO-induced relaxation in pulmonary artery.
Am J Physiol Heart Circ Physiol
272:
H904-H912,
1997.
43.
Zou, AP,
Fleming JT,
Falck JR,
Jacobs ER,
Gebremedhin D,
Harder DR,
and
Roman RJ.
Stereospecific effects of epoxyeicosatrienoic acids on renal vascular tone and K+-channel activity.
Am J Physiol Renal Fluid Electrolyte Physiol
270:
F822-F832,
1996.
This article has been cited by other articles:
|
|
 |
|
  E. E. Lloyd, S. P. Marrelli, and R. M. Bryan Jr. cGMP does not activate two-pore domain K+ channels in cerebrovascular smooth muscle Am J Physiol Heart Circ Physiol, June 1, 2009; 296(6): H1774 - H1780. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
X. Liu, C. Li, J. R. Falck, R. J. Roman, D. R. Harder, and R. C. Koehler Interaction of nitric oxide, 20-HETE, and EETs during functional hyperemia in whisker barrel cortex Am J Physiol Heart Circ Physiol, August 1, 2008; 295(2): H619 - H631. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. Zhu, I. Drenjancevic-Peric, S. McEwen, J. Friesema, D. Schulta, M. Yu, R. J. Roman, and J. H. Lombard Role of superoxide and angiotensin II suppression in salt-induced changes in endothelial Ca2+ signaling and NO production in rat aorta Am J Physiol Heart Circ Physiol, August 1, 2006; 291(2): H929 - H938. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
R. L. Macdonald, Z.-D. Zhang, M. Takahashi, E. Nikitina, J. Young, A. Xie, and L. Larkin Calcium sensitivity of vasospastic basilar artery after experimental subarachnoid hemorrhage Am J Physiol Heart Circ Physiol, June 1, 2006; 290(6): H2329 - H2336. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. Takeuchi, N. Miyata, M. Renic, D. R. Harder, and R. J. Roman Hemoglobin, NO, and 20-HETE interactions in mediating cerebral vasoconstriction following SAH Am J Physiol Regulatory Integrative Comp Physiol, January 1, 2006; 290(1): R84 - R89. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. Yang, J. W. Clark, R. M. Bryan, and C. S. Robertson Mathematical modeling of the nitric oxide/cGMP pathway in the vascular smooth muscle cell Am J Physiol Heart Circ Physiol, August 1, 2005; 289(2): H886 - H897. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
A. N. Swafford Jr., I. N. Bratz, J. D. Knudson, P. A. Rogers, J. M. Timmerman, J. D. Tune, and G. M. Dick C-reactive protein does not relax vascular smooth muscle: effects mediated by sodium azide in commercially available preparations Am J Physiol Heart Circ Physiol, April 1, 2005; 288(4): H1786 - H1795. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. Zhu, M. Yu, J. Friesema, T. Huang, R. J. Roman, and J. H. Lombard Salt-induced ANG II suppression impairs the response of cerebral artery smooth muscle cells to prostacyclin Am J Physiol Heart Circ Physiol, February 1, 2005; 288(2): H908 - H913. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 T. C. Resta Hypoxic regulation of nitric oxide signaling in vascular smooth muscle Am J Physiol Lung Cell Mol Physiol, August 1, 2003; 285(2): L293 - L295. [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
| Visit Other APS Journals Online |
