Compensatory role of NO in cerebral circulation of piglets chronically treated with indomethacin

doi:10.1152/ajpregu.00256.2001

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Compensatory role of NO in cerebral circulation of piglets chronically treated with indomethacin

Yifan Zhang and C. W. Leffler

Laboratory for Research in Neonatal Physiology, Department of Physiology, University of Tennessee Health Science Center, Memphis, Tennessee 38163

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

We hypothesize that inhibitory effects exist between prostanoids and nitric oxide (NO) in their contributions to cerebralcirculation. Piglets (1-4 days old) were divided into three chronicallytreated (6-8 days) groups: control piglets, piglets treated withindomethacin (75 mg/day), and piglets treated with N-nitro-L-arginine methyl ester (L-NAME, 100 mg · kg¹ · day¹). Pial arterioles dilated in response to hypercapnia similarlyamong the three groups (41 ± 4, 40 ± 6, and 45 ± 11%). Cerebrospinalfluid cAMP increased in control piglets, while cGMP increasedin indomethacin-treated piglets. L-NAME, but not 7-nitroindazole,inhibited the response to hypercapnia only in indomethacin-treatedpiglets (40 ± 6 vs. 17 ± 5%). Topical sodium nitroprusside oriloprost restored dilation in response to hypercapnia. Similarresults were obtained when the dilator was bradykinin. Pial arteriolesof control and L-NAME-treated piglets constricted in responseto ACh ( $-$ 24 ± 3%). However, those of indomethacin-treated pigletsdilated in response to ACh (15 ± 2%). This dilation was inhibitedby L-NAME. NO synthase activity, but not endothelial NO synthaseexpression, increased after chronic indomethacin treatment. Thesedata suggest that chronic inhibition of cyclooxygenase can increasethe contribution of NO to cerebrovascular circulatory controlinpiglets.

newborn; cranial window; cerebrovascular circulation; hypercapnia; acetylcholine; bradykinin; permissive

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

CEREBRAL BLOOD FLOW is well regulated. Prostanoids (PGs) and nitric oxide (NO) are among many vasoactive factors that contributeto the precise control of cerebral circulation. All the cellsin the brain can produce PGs. The quantities and types of PGs,which can be constrictors or dilators, are cell type and age specific(16). NO is a potent vasodilator that can produce relaxationof vessels in vivo and in vitro (13, 21). NO is released inthe conversion of L-arginine to L-citrulline via NO synthase (NOS).NO diffuses very easily from the endothelium and neurons intothe adjacent smooth muscle cells, activates soluble guanylyl cyclase,and increases the intracellular level ofcGMP.

Mechanisms of cerebrovascular circulatory control can change with development. Pearce et al. (27) found that the transitionfrom fetal to newborn life is associated with a decreased watercontent in the arteries, an increase in wall thickness, and anincrease in maximum contractile tension and stiffness. Hayashiand colleagues (9) reported a decrease in norepinephrine- andacetylcholine (ACh)-induced constrictions during maturation. NOhas been generally accepted as a major regulator of the adultcerebral circulation. However, PGs appear to be the dominant endothelium-derivedrelaxing factor (EDRF) in the regulation of cerebral circulationin newborn animals of several species, including humans (16).However, with maturation, the contribution of NO becomes moreimportant. For example, Willis and Leffler (37) found that asnewborn piglets matured to juvenile pigs, NO emerges as a significantEDRF in mediating the cerebral vasodilatory response to hypercapnia,but PGs still contributed to this response, albeit to a lesserextent. Zuckerman et al. (39) found that NO and PGs contributedto the pial arteriolar response to ACh in juvenile pigs, whileonly PG-associated vasoconstriction to ACh was found in newbornpigs.

Progressively accumulating evidence shows that, in addition to producing dose-dependent responses directly, PGs and NO canhave permissive functions in the regulation of cerebral circulation.By "permissive," we mean that presence of the mediator, not itsincreasing concentrations, is necessary to allow the dose-dependentresponse to an alternative stimuli to occur. In the cerebral vasculature,the permissive mechanism was first described in regard to thevascular response to ACh (3). Topically applied ACh causesconstriction of pial arterioles in the piglet and, at the sametime, a dose-dependent increase of PGs in the cerebrospinal fluid(CSF). Because the predominant PGs produced are dilators, onemight expect an augmentation of the constriction after inhibitionof PG production. However, indomethacin totally eliminates theconstrictive responses of pial arterioles. The thromboxane receptoragonist U-46619, at a constant subconstrictor concentration, restoredthe dose-dependent constriction in response to ACh. Furthermore,in intact piglets, the thromboxane receptor antagonist SQ-29548totally blocks the ACh-induced vasoconstriction. These resultsindicate that activation of the thromboxane receptor is necessaryand sufficient for the response to ACh (3).

Similarly, the role of prostacyclin in dilation of newborn pig cerebral arterioles to hypercapnia and histamine can be permissive(17, 18). In adult rats, NO might also play a permissive rolein the regulation of cerebral circulation. NO appears to be permissivein hypercapnia-induced cerebral vasodilation (11), but it isconventional in the pial arteriolar response to ACh (10).

The underlying mechanisms of the permissive actions of PGs and NO may be different. Surprisingly, the prostacyclin receptoris coupled to phospholipase C as well as adenylyl cyclase, andit is the phospholipase C pathway that seems to account for thepermissive function of prostacyclin in the piglet (26, 30).A minimal necessary cellular level of cGMP has been suggestedto be necessary for the permissive contribution of NO in the adultrat (38).

Numerous potential mechanisms exist for interactions between PGs and NO. One is that NO, or a related chemical species, canstimulate or inhibit cyclooxygenase (COX) by binding the hememoiety of the enzyme (32). NO can increase/decrease the half-lifeof COX-2 by affecting the autoinactivation of COX (7, 32).NO can also react with superoxide to produce peroxynitrite, andthe following peroxidation of lipid might affect the liberationof arachidonic acid from the cell membrane (6). The effectsof PGs on NOS are poorly understood, yet most data attribute theeffect of PGs on NO to cAMP (20). cAMP may affect the mRNA stabilityof NOS or its transcriptional activation (14). Others have suggestedthat the downregulation of tumor necrosis factor- $alpha$ by cAMP isinvolved (31).

Because PGs and NO can interact and, in the newborn, where PGs are higher, the role of NO appears to be small, we hypothesizethat inhibition of COX in the newborn will increase the role ofNO in cerebrovascular circulatorycontrol.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The animal protocols were reviewed and approved by the Animal Care and Use Committee of the University of Tennessee HealthScienceCenter.

Primary Culture of Endothelial Cells

Brains were extracted from newborn pigs anesthetized with ketamine and acepromazine. After homogenization of the cortex witha loose-fitting pestle in culture medium 199, 60- to 300-µm-diametermicrovessels were obtained by series filtration. To isolate theendothelial cells, the microvessels were treated with collagenase-dispase(1 mg/ml) for 2 h at 37°C and then subjected to Percoll densitygradient centrifugation. Cells were plated onto Matrigel-coated12-well cell culture plates and maintained in Dulbecco's modifiedEagle's medium containing 20% fetal bovine serum, 30 µg/ml endothelialcell growth supplement, 1 U/ml heparin, and antibiotic-antimycoticmixture. Cells were grown in a 5% CO₂-air incubator at 37°C for5-7 days until they reachedconfluence.

All experiments using cultured endothelial cells were performed on confluent quiescent cells. To achieve quiescence, cellswere exposed to serum-depleted medium (1% fetal bovine serum,0% endothelial cell growth supplement) for 15-24 h before theexperiments.

Western Blot Analysis for Endothelial NOS Protein

Freshly collected microvessels or cultured endothelial cells were suspended in Laemmli sample buffer (0.006% bromphenol blue,2.5% SDS, 0.125% Tris · HCl, 10% glycerol), and $beta$ -mercaptoethanolwas added to a final concentration of 5%. The samples were disruptedwith sonication (3 times for 10 s with 10-s intermissions) usingan ultrasonic cell processor (Sonics and Material, Danbury, CT).The samples were boiled for 10 min and then centrifuged for 10min at 5,000 g to clarify the cell lysate. Total protein concentrationof the samples was determined by the method described earlier(25).

The cell lysate was subjected to electrophoresis on 7.5% polyacrylamide gel. Proteins (60-80 µg) were loaded onto each laneand run overnight (30-40 V). Human lysate (Transduction Laboratories,Lexington, KY) was used as a positive control, and high-rangebiotinylated SDS-PAGE standards (Bio-Rad, Hercules, CA) were usedas molecular weight markers. After electrophoresis, the proteinswere transferred to nitrocellulose membranes in Towbin buffer[25 mM Tris, 192 mM glycine, 15% methanol (vol/vol), 0.05% SDS]by the wet transfer method (800 mA, 1.5 h). Nonspecific bindingsites were blocked by incubation of membranes with 5% bovine serumalbumin in Tris-buffered saline [10 mM Tris · HCl, 0.9% NaCl,pH 7.4, 0.05% Tween 20 (vol/vol)] for 1 h. For endothelial NOS(eNOS) detection, the membrane was incubated with polyclonal eNOSantibody (Transduction Laboratories; 1:2,000 dilution) for 2 hat room temperature. After the membrane was washed three timesfor 15 min each with Tris-buffered saline, the membrane was incubatedwith horseradish peroxidase-conjugated donkey anti-mouse immunoglobulinG (Jackson ImmunoResearch Laboratories, West Grove, PA) for 2h at room temperature. Streptavidin-biotin-horseradish peroxidasecomplex was added to the second antibody incubation medium todetect biotinylated standards. The blot was then developed witha chemiluminescence detection system (Du Pont, Boston, MA), andthe protein band was detected by autoradiography. For actin detection,the membrane was incubated with monoclonal actin antibody (Chemicro,Temecula, CA; 1:5,000 dilution) at the first antibody incubationstep with subsequent treatment as for eNOSdetection.

Animal Groups and Treatments

Fifty-one newborn piglets (2.2 ± 0.3 kg) were randomly assigned to three groups simultaneously (typically 2-3 piglets perweek, with 1 control and the others in indomethacin and/or L-NAMEgroups).

The control group consisted of 21 piglets (9 ± 2 days at the end of treatment): 11 were subjected to a sham procedure fororal indomethacin, and the other 10 were housed with indomethacin-and L-NAME-treated piglets for 6-8 days. The indomethacin group(n = 24, 11 ± 2 days at the end of treatment) was treated withindomethacin (75-mg sustained-released capsule po, twice a day,for 6-8 days). The L-NAME group (n = 6, 11 ± 3 days at the endof treatment) was treated with L-NAME (100 mg · kg¹ · day¹ ip for 6-8days).

At the end of treatment, animals were anesthetized with ketamine hydrochloride (33 mg/kg im) and acepromazine (3.3 mg/kg im).The anesthesia was maintained with $alpha$ -chloralose during the experiment(30-40 mg/kg initially, supplemented with 7 mg · kg¹ · h¹). A catheter was placed in the femoral artery to record systemicblood pressure and to sample arterial blood for the measurementof pH, PCO₂, and PO₂. A second catheter was placed in the femoralvein for anesthesia and experimental drug administration. Animalsunderwent a tracheotomy with insertion of an endotracheal tubeand mechanically ventilated with room air to maintain arterialpH, PCO₂, and PO₂ within the normal range. The core temperaturewas monitored with a rectal probe and maintained at 37.5-38.5°C.The indomethacin-treated piglets were given indomethacin acutely(5 mg/kg iv) before the experiment to ensure complete block ofCOX during cranial window experiment. This dose was repeated every90min.

Cranial Window Placement and Pial Arteriolar Monitoring

After catheter placement and tracheotomy, the scalp was surgically removed, and a 2-cm-diameter hole was cut in the skullover the parietal cortex. Bone wax was applied to stop bleeding.The dura was gently cut and pulled over the cut bone edge. Carewas taken to avoid contact with the brain surface. A stainlesssteel cranial window with a glass pane was placed in the holeand solidly cemented sequentially with bone wax, Superglue, andmeditone. A dissecting microscope with a mounted videocamera wasused to observe pial arterioles (50-140 µm). Vessel diameter wasmeasured with a video microscaler. The space under the windowwas filled with artificial CSF (aCSF; in mg/l: 220 KCl, 1,132MgCl₂, 221 CaCl₂, 7,710 NaCl, 401 urea, 665 dextrose, 2,066 NaHCO₃).The aCSF was warmed in a water bath to 37°C and bubbled with 6%CO₂-6% O₂-88% N₂ to maintain approximate values of pH 7.33, 45mmHg PCO₂, and 45 mmHg PO₂.

After an initial observation period of 30 min, 50- to 140-µm-diameter pial arterioles were measured and recorded. Mean arterialpressure and core temperature were recorded. At the end of eachtested response, an arterial blood gas sample was drawn, and thearea under the window was gently flushed with fresh aCSF to removethe previous stimulus and allow the vessels to recover to baselinediameters before the nextmeasurement.

Dilations of pial arterioles in response to topical isoproterenol (10⁶ M; Sigma Chemical, St. Louis, MO) were recorded at the beginningand end of each experiment to ensure consistent responsivenessof pial arterioles to stimuli and stability of the preparationthroughout the experiment. Preparations that demonstrated >15%decline in response to isoproterenol from beginning to end werediscarded.

Pial Arteriolar Response to Hypercapnia

Piglets were mechanically ventilated with room air plus supplemental CO₂ to achieve 55-65 mmHg PCO₂. Our goal was to determinethe involvement of PGs and/or NO in mediating the pial arteriolardilation to hypercapnia in these three groups. In the controlgroup, responses of the pial arterioles were recorded before andafter the administration of L-NAME and indomethacin and in thepresence of a subdilatory dose of iloprost. In the indomethacingroup, responses were recorded before and after topical administrationof L-NAME and 7-nitroindazole (7-NI) and in the presence of subdilatoryconcentrations of iloprost (0.5 × 10⁹ and 1 × 10⁹ M), sodium nitroprusside (SNP, 0.5 × 10⁷ and 1 × 10⁷ M), or iloprost + SNP. In the L-NAME group, the pial arteriolardilatory responses to hypercapnia were recorded before and afterthe application ofindomethacin.

Pial Arteriolar Response to Topical ACh

Topical ACh (10⁵ M; Sigma Chemical) was applied to the cranial window to determine the responses of pial arterioles to AChand to investigate possibly different roles of PGs and NO in theseresponses in the three groups of piglets. In control piglets,responses were recorded before and after the application of L-NAMEand indomethacin. In indomethacin-treated piglets, responses wererecorded before and after L-NAME (10³ M) administration and in the presence of U-46619 (0.5 × 10⁸ M). In L-NAME-treated piglets, the responses before and afterindomethacin administration werecompared.

Pial Arteriolar Response to Topical Bradykinin

Bradykinin (BK, 10⁷ M; Sigma Chemical) was applied topically. In control piglets, the responses to BK were recorded beforeand 1 h after application of topical L-NAME (10³ M) or indomethacin (5 mg/kg iv) to investigate the respectivecontributions of PG and NO. In indomethacin-treated piglets, theresponses before and after administration of L-NAME or 7-NI (25mg/ml dissolved in mineral oil, 50 mg/kg ip) or in the presenceof SNP (0.5 × 10⁷ and 1 × 10⁷ M) after L-NAME wererecorded.

cAMP and cGMP Assay

CSF samples were carefully collected by flushing the closed window with aCSF. The cranial window has a volume of 500 µl, andonly 300 µl were collected for the detection of cyclicnucleotides.

cAMP levels in CSF were determined by radioimmunoassay. CSF samples were acetylated with 2:1 triethylamine-acetic anhydrideimmediately before the assay to increase the sensitivity. ¹²⁵I-labeled cAMP and rabbit anti-cAMP antibody were added to thesamples and incubated overnight. Polyethylene glycol (25%) wasadded to precipitate antibody-bound cAMP. The cAMP concentrationin the CSF was calculated from the standardcurve.

The cGMP levels in the CSF samples were measured with an ELISA kit (Stratagene, La Jolla, CA). CSF samples were acetylatedwith 2:1 triethylamine-acetic anhydride immediately before theywere applied to 96-well plates. After the samples were incubatedwith rabbit anti-cGMP on a shaker for 1 h at room temperature,horseradish peroxidase-conjugated cGMP was added to each welland incubated at 4°Covernight.

After the plates were washed, tetramethylbenzidine-H₂O₂ substrate was added. After 10 min, phosphoric acid was added to stopthe color-developing reaction. Concentrations of cGMP were calculatedby measuring the absorption at 450 nm and constructing a standardcurve.

NOS Assay

The activity of NOS, including eNOS, neuronal NOS (nNOS), and inducible NOS, was determined using an NOS assay kit (CaymanChemical, Ann Arbor, MI). Briefly, the fresh isolated microvesselswere homogenized, and then the reaction mixture, including [³H]arginine, CaCl₂, and NADPH, was added. After the sample wasincubated at room temperature for 60 min, resin was added to bindunreacted arginine. Samples were transferred to spin cups andcentrifuged; the elutant was collected, mixed with scintillationfluid, and thencounted.

Statistical Analysis

Values are means ± SE. Comparisons among populations were made by analysis of variance with repeated measures. Fisher's protectedleast significant difference was used to determine differencesbetween groups. Significant responses to stimuli (i.e., comparisonswith zero change) were determined by Student's t-tests. P < 0.05was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

eNOS Protein Levels in Cultured Endothelial Cells

Treatment with NS-398, indomethacin, arachidonic acid, or interleukin-1 $beta$ for 24 h did not change the expression of eNOS proteinin primary cultures of endothelial cells compared with the control(Fig. 1).

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Fig. 1. A: endothelial nitric oxide synthase (eNOS) expression in piglet endothelial cells in primary culture. B: actin expression on the same membranes. AA, arachidonic acid; IL-1 $beta$ , interleukin-1 $beta$ .

eNOS Protein Levels in Microvessels

The protein levels of eNOS did not differ significantly among microvessels from the three groups of piglets (Fig. 2). (Weperformed these experiments 4 times and, according to quantitativeanalysis using NIH Image 1.62, could detect no significant difference.)

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Fig. 2. A: eNOS expression in freshly collected cerebral microvessels of piglets. B: actin expression on the same membranes. L-NAME, N-nitro-L-arginine methyl ester.

NOS Activities in Microvessels

The NOS activity was higher in the microvessels from the indomethacin-treated piglets than from the control group. Furthermore,as expected, the NOS activity in microvessels from L-NAME-treatedpiglets was significantly reduced (Fig. 3).

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Fig. 3. Total NOS activities, measured by L-arginine-to-L-citrulline conversion rate in freshly isolated cerebral microvessels of piglets. Values are means ± SE. *Statistical significance compared with control group, P < 0.05.

Pial Arteriolar Responses

Chronic treatment of piglets with L-NAME increased mean blood pressure (89 ± 17 mmHg) compared with the control group (65± 11 mmHg) and the indomethacin group (69 ± 9 mmHg). The bloodgas and pH were not different among the groups. Initial diametersof pial arterioles were similar among the control, indomethacin,and L-NAME groups [control: small, 57 ± 7 µm (n = 21); large,94 ± 9 µm (n = 18); indomethacin: small, 62 ± 8 µm (n = 25); large,89 ± 7 µm (n = 24); L-NAME: small, 65 ± 6 (n = 6); large, 99 ±8 µm (n = 8)]. Also, smaller and larger vessels responded similarlyin all experiments. Therefore, only responses recorded from smaller(~60-70 µm) arterioles are reportedbelow.

Response to hypercapnia. During control periods and hypercapnia challenges, the arterial PCO₂ values were not significantly different among the threegroups.

In the control, indomethacin, and L-NAME groups, the pial arterioles dilated to the same degree in response to hypercapnia(Fig. 4). In neither the control nor the L-NAME-treated groupsdid acute application of L-NAME affect the dilation. Conversely,in indomethacin-treated piglets, the application of L-NAME significantlydecreased the dilatory response to hypercapnia.

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Fig. 4. Effects of hypercapnia on pial arteriolar diameters in control (A, n = 9), indomethacin-treated (B, n = 10), and L-NAME-treated piglets (C, n = 6). In each group, responses were measured with vehicle under the cranial window after topical L-NAME (10³ M) or indomethacin (5 mg/kg iv) or topical L-NAME (10³ M) + indomethacin (5 mg/kg iv). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

The dilatory response to hypercapnia in control piglets, which was inhibited by indomethacin treatment, was restored by subdilatoryconcentrations of iloprost, a prostacyclin analog (Fig. 5), indicatingthat the role of PGs in this phenomenon might be permissive.

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Fig. 5. Dilation of pial arterioles of piglets in response to hypercapnia in control group (n = 9 piglets). Responses were measured with vehicle under the cranial window after topical L-NAME (10³ M), topical L-NAME (10³ M) + indomethacin (Indo, 5 mg/kg iv), and topical iloprost (0.5 × 10⁹ and 1 × 10⁹ M) after administration of L-NAME (10³ M) + indomethacin (5 mg/kg iv). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with response after L-NAME + indomethacin, P < 0.05.

In indomethacin-treated piglets, L-NAME inhibited the dilation to hypercapnia. This inhibition was reversed by the applicationof the NO donor SNP in subdilatory concentrations (Fig. 6). Therefore,NO may play a permissive role in the response to hypercapnia.A doubling of the dosage of SNP did not have a greater effect,further indicating that the role of NO is a permissive one.

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Fig. 6. Dilation of pial arterioles of piglets in response to hypercapnia in indomethacin group (n = 10 piglets). Responses were measured with the vehicle under the cranial window after topical L-NAME (10³ M), topical L-NAME (10³ M) + iloprost (Ilo, 0.5 × 10⁹ and 1 × 10⁹ M), topical L-NAME (10³ M) + sodium nitroprusside (SNP, 0.5 × 10⁷ and 1 × 10⁷ M), and topical L-NAME (10³ M) + iloprost (0.5 × 10⁹ and 1 × 10⁹ M) + SNP (0.5 × 10⁷ and 1 × 10⁷ M). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with response after L-NAME in indomethacin group, P < 0.05.

Iloprost also restored the dilatory response to hypercapnia inhibited by topical administration of L-NAME in the indomethacin-treatedgroup (Fig. 6). Application of iloprost and SNP together did notfurther increase the previously inhibited dilatory effect by L-NAME.

In the control group, the cAMP level in CSF increased significantly in response to hypercapnia, while it remained nearly unchangedin the indomethacin-treated piglets (Fig. 7).

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Fig. 7. A: effects of hypercapnia on cortical production of cAMP (n = 6 piglets). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with cAMP production in response to hypercapnia in control group, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05. B: effects of hypercapnia on cortical production of cGMP (n = 6 piglets). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with cGMP production in response to hypercapnia in indomethacin group, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

The basal cGMP level was higher in the indomethacin-treated piglets. In contrast to the control piglets, cGMP increased significantlyin response to hypercapnia in the indomethacin-treated piglets,and this increase could be inhibited by the topical applicationof L-NAME (Fig. 7).

Response to ACh. In contrast to the constrictor response to ACh in control and L-NAME-treated piglets, the pial arterioles dilated in responseto ACh in indomethacin-treated piglets. Similar to the responseto hypercapnia, this dilation could be significantly inhibitedby L-NAME administration (Fig. 8).

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Fig. 8. Effects of topical ACh (10⁵ M) on pial arteriolar diameter in control (A, n = 7), indomethacin-treated (B, n = 11), and L-NAME-treated piglets (C, n = 6). Piglets in each group were examined with vehicle under the cranial window after topical L-NAME (10³ M) or indomethacin (5 mg/kg iv) or or topical L-NAME (10³ M) + indomethacin (5 mg/kg iv). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

In indomethacin-treated piglets, the dilatory response to ACh, which was inhibited by topical administration of L-NAME (10³ M), was reversed to constriction by topical U-46619 (0.5 × 10⁸ M; Fig. 9). In the control group, the presence of U-46619, athromboxane receptor agonist, at this concentration had no effecton the already evident constrictor effect of ACh.

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Fig. 9. Effects of topical ACh (10⁵ M) on pial arteriolar diameter in control (A, n = 7) and indomethacin-treated piglets (B, n = 11). Responses were observed with topical vehicle, L-NAME (10³ M), and L-NAME (10³ M) + U-46619 (0.5 × 10⁸ M). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with control group, P < 0.05. $Dagger$ Statistical significance compared with response after L-NAME treatment in indomethacin group, P < 0.05.

In the control and indomethacin-treated groups, the cAMP levels in CSF did not change significantly after topical applicationof ACh, although the cAMP levels were lower in the indomethacin-treatedpiglets than in the control group (Fig. 10A).

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Fig. 10. Effects of ACh on cortical production of cAMP (A) and cGMP (B). Values are means ± SE (n = 6 piglets). *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

On the other hand, the basal cGMP level was higher in the indomethacin-treated piglets. Furthermore, cGMP increased significantlyin response to ACh in this group (Fig. 10B).

Response to BK. In control piglets, inhibition of NOS with L-NAME did not decrease the dilation of pial arterioles in response to BK, whilethe administration of indomethacin nearly totally eliminated thisdilatory response (Fig. 11). Conversely, in indomethacin-treatedpiglets, L-NAME significantly inhibited the dilatory responseto BK.

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Fig. 11. Effect of topical bradykinin (10⁷ M) on pial arterioles in control (A, n = 9) and indomethacin-treated piglets (B, n = 8). Responses are shown with topical vehicle, L-NAME (10³ M), or L-NAME (10³ M) + indomethacin (5 mg/kg iv). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

In contrast to the dilatory response to hypercapnia, iloprost (0.5 × 10⁹ and 1 × 10⁹ M) alone could not restore the dilation to BK in indomethacin-treatedpiglets after L-NAME treatment (data not shown). A subdilatoryconcentration of SNP (0.5 × 10⁷ and 1 × 10⁷ M), however, did restore it (Fig. 12).

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Fig. 12. Effect of topical bradykinin (10⁷ M) on pial arterioles in control (A, n = 9) and indomethacin-treated piglets (B, n = 8). Responses are shown with topical vehicle, L-NAME (10³ M), and L-NAME (10³ M) + SNP (0.5 × 10⁷ and 1 × 10⁷ M). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with response after L-NAME treatment in indomethacin group, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

In the control group, cAMP increased significantly in response to BK. This increase could be largely inhibited by L-NAME treatment,while it was not further decreased by indomethacin. cAMP levels,significantly lower in CSF of indomethacin-treated piglets, remainedflat in response to BK (Fig. 13A).

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Fig. 13. A: effects of topical bradykinin on cortical production of cAMP. Values are means ± SE (n = 6 piglets). *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with bradykinin alone (P < 0.05). $Dagger$ Statistical significance compared with control group, P < 0.05. B: effects of topical bradykinin on cortical production of cGMP. Values are means ± SE (n = 6 piglets). *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with cGMP production in response to bradykinin in indomethacin group, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

The basal level of cGMP was higher in the indomethacin-treated piglets than in the control group. Only in indomethacin-treatedpiglets did the level of cGMP increase significantly in responseto BK. This increase was inhibited by the topical applicationof L-NAME (Fig. 13B).

Effect of 7-NI. In piglets chronically treated with indomethacin, the application of 7-NI, a specific nNOS inhibitor, did not, in contrastto L-NAME, inhibit the dilatory response of pial arterioles toBK (Fig. 14) or hypercapnia (Fig. 15).

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Fig. 14. Effect of topical bradykinin (10⁷ M) on pial arterioles in control (A, n = 9) and indomethacin-treated piglets (B, n = 8). Responses were recorded with topical vehicle under the cranial window after L-NAME (10³ M) or 7-nitroindazole (7-NI, 50 mg/kg ip). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $dagger$ Statistical significance compared with response after L-NAME treatment in indomethacin group, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05.

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Fig. 15. Effect of hypercapnia on pial arterioles in control (A, n = 9) and indomethacin-treated piglets (B, n = 8). Responses were recorded with topical vehicle under the cranial window after L-NAME (10³ M) or 7-NI (50 mg/kg ip). Values are means ± SE. *Statistical significance compared with vehicle, P < 0.05. $Dagger$ Statistical significance compared with control group, P < 0.05. $dagger$ Statistical significance compared with response after L-NAME treatment in indomethacin group, P < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The present study demonstrates overall that chronic treatment of newborn pigs with the COX inhibitor indomethacin causes transformationof the major dilator influence in the cerebrovascular circulationfrom PG to NO. First, chronic treatment with indomethacin or L-NAMEdoes not affect eNOS expression in cerebral microvessels, eventhough both substances affect NOS activity (increase or decrease,respectively). Second, chronic treatment of piglets with indomethacinor L-NAME does not change the pial arteriolar dilatory responsesto hypercapnia or BK. Third, although the dilatory responses remain,chronic COX inhibition results in a change in the underlying mechanismfrom a PG-dependent to an NO-dependent mechanism, accompaniedby an increase in NO's second messenger, cGMP. Conversely, chronicinhibition of NOS causes no change in the role of PGs in the dilatoryresponses. Fourth, PGs and NO can serve permissive functions inindomethacin-treated piglets. Fifth, chronic treatment with indomethacinresults in dilatory responses to ACh along with increases in cGMP,which are not normally present in piglets. Sixth, the increasedcontribution of NO after chronic treatment with indomethacin cannotbe inhibited by 7-NI, suggesting that the source is notnNOS.

PGs, particularly prostacyclin, are dominant EDRFs in the cerebral circulation of newborns of several species, including humans(16). Contributions of PGs to dilator responses to numerousstimuli, including hypercapnia, histamine, and hypotension, havebeen demonstrated (16). This PG dominance, however, appearsto diminish with age, and the role of NO becomes more predominantin adult animals (10, 34, 37, 39).

Although it is recognized that there is "cross talk" between products of the NOS and COX pathways, results are inconsistentwith respect to whether the cross talk is stimulatory or inhibitory(5). Nitroglycerin, an NO donor, stimulates PG synthesis inendothelial cells (19), while NO inhibits the production ofPGs in chrondrocytes and LPS-stimulated macrophages (2). NOmay exert divergent effects on constitutive COX-1 and inducibleCOX-2 (5). We hypothesized that there can be inhibitory effectsbetween the COX and the NOS pathway and that chronically inhibitingone of these systems can enhance the role of theother.

It appears that when one system is inhibited, compensatory mechanisms are rapidly recruited to restore normal response. Forexample, Irikura et al. (12) demonstrated that, in nNOS knockoutmice, alternative mediators could replace the function of NO.In dogs, a compensatory role of PGs in the regulation of coronarycirculation was implied after sustained inhibition of NOS (29).Son and Zuckerman (34), using the same animal model used inthe present experiment, demonstrated that chronic inhibition ofCOX did not change the cerebral vasodilator response of pigletsto hypercapnia but that the underlying mechanism appeared to bedifferent, with a role for NO appearing. The present study confirmsand extends the findings of Son and Zuckerman. We demonstratethat by chronically inhibiting COX, the enzyme required to producePGs, the pial arteriolar responses to hypercapnia and BK seemto shift from requiring PGs to requiring NO, and the classic NO-dependentdilation to ACh becameevident.

Chronic inhibition of NOS with L-NAME decreased the NOS activity in the piglets without affecting eNOS expression. However,chronic NOS inhibition was without effect on pial arteriolar responsesto hypercapnia, BK, or ACh. This result was not entirely unexpected,because acute L-NAME treatment does not alter pial arteriolarresponse to these stimuli, suggesting a minimal role of endogenousNO in the intact newborn pig cerebral circulation. Because PGsare playing a permissive role (see below) in the regulation ofcerebral circulation in response to the stimuli, even if COX expressionactually were enhanced, no change in dilator response to hypercapniaor BK or constriction to ACh would be expected. Whether chronicinhibition of NOS in the adult pig would augment the role of PGsin cerebrovascular control remains to bedetermined.

It has been shown that the role of prostacyclin underlying the dilatory response to hypercapnia can be permissive (16),which means that prostacyclin, instead of causing the relaxationof smooth muscle cells by directly increasing cAMP, can allowhypercapnia to enhance cAMP to produce dilation. In the presentexperiments, application of iloprost, a prostacyclin analog, restorednot only the indomethacin-inhibited dilatory response in the controlpiglets, but also the L-NAME-inhibited dilation in the indomethacin-treatedpiglets. We suggest that the downstream mechanism responsiblefor the permissive effect of prostacyclin was not lost duringchronic treatment. This restoration could not be further enhancedby doubling the dose of iloprost or by administering iloprost+ SNP, which further supports the concept that their actions arepermissive andalternative.

It is noteworthy that, in the indomethacin-treated piglets, SNP, an NO donor, also can restore the dilatory response of pialarterioles to hypercapnia at a subdilatory concentration. Similarto the case with iloprost, doubling the dosage did not furtherdilate the arterioles. It has been suggested that NO might bethe final mediator of smooth muscle relaxation or can allow anotherdilatory mediator to act (10). Hence, it appears that whetherthe actions of dilatory regulators are conventional or permissivedepends on the nature, and possibly the strength, of the stimulias well as the maturity of theanimal.

Chronic indomethacin treatment changes the pial arteriolar response to ACh from constriction to dilation. The dilation isinhibited by topical application of L-NAME. Zuckerman et al. (39)demonstrated that the constriction in response to ACh in pigletswas PG dependent, while the biphasic (constriction-dilation) responseto ACh in juvenile pigs was dependent on PGs for the initial constriction,as in the newborn, but dependent on NO for the prolonged dilation(39). We report that the pial arteriolar response to ACh afterindomethacin treatment is more adultlike, showing only dilationand relying solely on NO. Of course, the lack of initial constrictionis the same as with the acute treatment withindomethacin.

The role of PGs in the newborn's pial arteriolar constriction to ACh is also permissive (3). In the present study, we foundthat a subconstrictor concentration of U-46619, a thromboxanereceptor agonist, can restore the initial constriction to AChin chronically indomethacin-treated piglets just as in the controlpiglets. Therefore, the permissive mechanism for constrictionto ACh remains in the chronically indomethacin-treatedpiglet.

A variety of mediators, including oxygen radicals, NO, and endothelium-derived hyperpolarizing factors, have been reportedto mediate dilation of blood vessels to BK (15, 23). We foundthat, in control and indomethacin-treated piglets, pial arteriolesdilate in response to BK. The dilator response of control pigletswas only mildly inhibited by L-NAME but was nearly abolished byindomethacin. Although NO does not appear to be an important mediatorin control piglets, it is much more important for the pial arteriolarresponse to BK in the indomethacin-treated piglets. The inhibitionby L-NAME of the dilator response to BK can be reversed by a subdilatoryconcentration of SNP, suggesting that NO may play a permissiverolehere.

It is generally assumed that the vasodilator effects of PGs are mediated by stimulation of adenylyl cyclase, while the dilatoreffects of NO are mediated by guanylyl cyclase. In the presentstudy, we found that the basal level of cAMP in CSF decreasedafter chronic indomethacin treatment, while that of cGMP increased.In contrast to the control piglets, the level of cGMP, insteadof cAMP, increased in the indomethacin-treated piglets along withthe pial arteriolar dilatory responses to hypercapnia and BK.The increase in cGMP could be inhibited by topical applicationof L-NAME, suggesting an increased activity of NOS after the indomethacintreatment. Furthermore, in indomethacin-treated, but not in control,piglets, cGMP was increased by the administration of ACh. Thisincrease, similarly, was eliminated by L-NAME.

The data from the L-arginine-to-L-citrulline conversion experiment clearly demonstrated that NOS activity increased in microvesselsof indomethacin-treated piglets and decreased in microvesselsof L-NAME-treated piglets. However, we could not detect any changesin eNOS protein levels after treating cultured endothelial cellsfrom newborns with the PG precursor arachidonic acid, the COX-2inhibitor NS-398, indomethacin, or interleukin-1 $beta$ . In addition,contrary to our anticipation from vascular responses, the eNOSprotein levels also were not different among the microvesselsfrom the three chronic pigletgroups.

We considered the possibility that the other constitutive isoform of NOS, nNOS, could contribute to the compensatory enhancementof the role of NO in the indomethacin-treated piglets. In fact,selective nNOS inhibitors reduce the cerebral vasodilator responseto hypercapnia in rats (37). Some studies also suggest thatnNOS-derived NO acts permissively in mediating this hypercapnicresponse (24). However, in the present study, 7-NI, the specificnNOS inhibitor, did not affect the pial arteriolar dilatory responseto hypercapnia or BK in the indomethacin-treated piglets, suggestingthat nNOS probably is not involved. It is unlikely that the doseof 7-NI was insufficient, because it was the same as that usedin the adult rat studies cited above (36). In this study, nNOSprotein was undetectable in the cerebral microvessels of all threegroups using Western blot (data notshown).

Although chronic indomethacin treatment makes the responses of piglets appear more adultlike, significant differences remainbetween indomethacin-treated piglets and juvenile pigs. First,in contrast to juvenile pigs (37), iloprost restored the dilatoryresponse to hypercapnia that had been inhibited by L-NAME in indomethacin-treatedpiglets. Second, SNP reversed the decreased dilatory responseto hypercapnia and BK caused by L-NAME in indomethacin-treatedpiglets, but not in juvenile pigs (37). Third, we could notdetect any increase in eNOS protein levels in the microvesselsof indomethacin-treated piglets, while in juvenile pigs, eNOSexpression is much higher than in newborns (25). Finally, injuvenile pigs, the full responses of pial arterioles to hypercapniaand BK require PGs and NO (39).

The mechanism by which the role of NO increases after chronic treatment with indomethacin is not known. We do know that thelevel of PGs in CSF decreases with the maturation of the animal,so it is possible that the higher level of PGs in the newbornis having sustained inhibitory effects on the NO system. Whenthe PG concentration decreases with maturation, this inhibitoryeffect decreases, enhancing the activity of the NOsystem.

In conclusion, the results from this study support the hypothesis that chronically inhibiting COX causes an increased influenceof NO in the newborn cerebrovascular circulation. Hence, the inhibitionof COX did not change the dilatory response of pial arteriolesto hypercapnia or BK but did produce a dilation in response toACh, which is not present in the untreated newborn pigs. All thesedilations can be blocked by L-NAME in chronically indomethacin-treatedpiglets, suggesting that an enhanced role of NO underlies theseeffects. Along with the dilatory responses to hypercapnia andBK, CSF cAMP increased in control piglets, while cGMP increasedin indomethacin-treated piglets. The NOS activity increased inindomethacin-treated piglets and decreased in L-NAME-treated piglets.On the other hand, eNOS protein levels did not change in the microvessels,and nNOS seems not to be involved, suggesting that the increaseor decrease in activity of NOS was independent of protein level.The mechanism responsible for enhancement of the NO system needsfurtherinvestigation.

	ACKNOWLEDGEMENTS

We thank Alex Fedinec for technical assistance, Danny Morse for help with the figures, and Jin Emerson-Cobb for editorialhelp.

	FOOTNOTES

This research was funded by the National Heart, Lung, and BloodInstitute.

Address for reprint requests and other correspondence: C. W. Leffler, Dept. of Physiology, 894 Union Ave., Memphis, TN 38163(E-mail: cleffler{at}physio1.utmem.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

10.1152/ajpregu.00256.2001

Received 12 May 2001; accepted in final form 24 September 2001.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

1. Aeberhard, EE, Henderson SA, Arabolos NS, Griscavage JM, Castro FE, Barrett CT, and Ignarro LJ. Nonsteroidal anti-inflammatory drugs inhibit expression of the inducible nitric oxide synthase gene. Biochem Biophys Res Commun 208: 1053-1059, 1995[ISI][Medline].

2. Amin, AR, Patel RN, Thakker GD, Lowenstein CJ, Attur MG, and Abramson SB. Superinduction of cyclooxygenase-2 activity in human osteoarthritis-affected cartilage: influence of nitric oxide. J Clin Invest 99: 1231-1237, 1997[ISI][Medline].

3. Armstead, WM. Role of nitric oxide and cAMP in prostaglandin-induced pial arterial vasodilation. Am J Physiol Heart Circ Physiol 268: H1436-H1440, 1995[Abstract/Free Full Text].

4. Cillari, E, Milano S, D'Agostino P, Di Bella G, La Rosa M, Barbera C, Ferlazzo V, Cammarata G, Grimaudo S, Tolomeo M, and Feo S. Modulation of nitric oxide production by tetracyclines and chemically modified tetracyclines. Adv Dent Res 12: 126-130, 1998[Abstract/Free Full Text].

5. Clancy, R, Varenika B, Huang W, Ballou L, Attur M, Amin AR, and Abramson SB. Nitric oxide synthase/COX cross-talk: nitric oxide activates COX-1 but inhibits COX-2-derived prostaglandin production. J Immunol 165: 1582-1587, 2000[Abstract/Free Full Text].

6. Davidge, ST, Baker PN, Laughlin MK, and Roberts JM. Nitric oxide produced by endothelial cells increases production of eicosanoids through activation of prostaglandin H synthase. Circ Res 77: 274-283, 1995[Abstract/Free Full Text].

7. Egan, RW, Paxton J, and Kuehl FA, Jr. Mechanism for irreversible self-deactivation of prostaglandin synthetase. J Biol Chem 251: 7329-7335, 1976[Abstract/Free Full Text].

8. Guastadisegni, C, Minghetti L, Nicolini A, Polazzi E, Ade P, Balduzzi M, and Levi G. Prostaglandin E₂ synthesis is differentially affected by reactive nitrogen intermediates in cultured rat microglia and RAW 264.7 cells. FEBS Lett 413: 314-318, 1997[ISI][Medline].

9. Hayashi, S, Park MK, and Kuehl TJ. Higher sensitivity of cerebral arteries isolated from premature and newborn baboons to adrenergic and cholinergic stimulation. Life Sci 35: 253-260, 1984[ISI][Medline].

10. Iadecola, C, and Zhang F. Permissive and obligatory roles of NO in cerebrovascular responses to hypercapnia and acetylcholine. Am J Physiol Regulatory Integrative Comp Physiol 271: R990-R1001, 1996[Abstract/Free Full Text].

11. Iadecola, C, Zhang F, and Xu X. SIN-1 reverses attenuation of hypercapnic cerebrovasodilation by nitric oxide synthase inhibitors. Am J Physiol Regulatory Integrative Comp Physiol 267: R228-R235, 1994[Abstract/Free Full Text].

12. Irikura, K, Huang PL, Ma J, Lee WS, Dalkara T, Fishman MC, Dawson TM, Snyder SH, and Moskowitz MA. Cerebrovascular alterations in mice lacking neuronal nitric oxide synthase gene expression. Proc Natl Acad Sci USA 92: 6823-6827, 1995[Abstract/Free Full Text].

13. Katusic, ZS, Marshall JJ, Kontos HA, and Vanhoutte PM. Similar responsiveness of smooth muscle of the canine basilar artery to EDRF and nitric oxide. Am J Physiol Heart Circ Physiol 257: H1235-H1239, 1989[Abstract/Free Full Text].

14. Koide, M, Kawahara Y, Nakayama I, Tsuda T, and Yokoyama M. Cyclic AMP-elevating agents induce an inducible type of nitric oxide synthase in cultured vascular smooth muscle cells. Synergism with the induction elicited by inflammatory cytokines. J Biol Chem 268: 24959-24966, 1993[Abstract/Free Full Text].

15. Kontos, HA, Wei EP, Kukreja RC, Ellis EF, and Hess ML. Differences in endothelium-dependent cerebral dilation by bradykinin and acetylcholine. Am J Physiol Heart Circ Physiol 258: H1261-H1266, 1990[Abstract/Free Full Text].

16. Leffler, CW. Prostanoids: intrinsic modulators of cerebral circulation. News Physiol Sci 12: 72-77, 1997[Abstract/Free Full Text].

17. Leffler, CW, Fedinec AL, and Shibata M. Prostacyclin receptor activation and pial arteriolar dilation after endothelial injury in piglets. Stroke 26: 2103-2110, 1995[Abstract/Free Full Text].

18. Leffler, CW, Mirro R, Pharris LJ, and Shibata M. Permissive role of prostacyclin in cerebral vasodilation to hypercapnia in newborn pigs. Am J Physiol Heart Circ Physiol 267: H285-H291, 1994[Abstract/Free Full Text].

19. Levin, RI, Jaffe EA, Weksler BB, and Tack-Goldman K. Nitroglycerin stimulates synthesis of prostacyclin by cultured human endothelial cells. J Clin Invest 67: 762-769, 1981.

20. Marotta, P, Sautebin L, and Di Rosa M. Modulation of the induction of nitric oxide synthase by eicosanoids in the murine macrophage cell line J774. Br J Pharmacol 107: 640-641, 1992[ISI][Medline].

21. Marsden, PA, Schappert KT, Chen HS, Flowers M, Sundell CL, Wilcox JN, Lamas S, and Michel T. Molecular cloning and characterization of human endothelial nitric oxide synthase. FEBS Lett 307: 287-293, 1992[ISI][Medline].

22. Minghetti, L, Nicolini A, Polazzi E, Creminon C, Maclouf J, and Levi G. Inducible nitric oxide synthase expression in activated rat microglial cultures is downregulated by exogenous prostaglandin E₂ and by cyclooxygenase inhibitors. Glia 19: 152-160, 1997[ISI][Medline].

23. Mombouli, JV, Illiano S, Nagao T, Scott-Burden T, and Vanhoutte PM. Potentiation of endothelium-dependent relaxations to bradykinin by angiotensin I converting enzyme inhibitors in canine coronary artery involves both endothelium-derived relaxing and hyperpolarizing factors. Circ Res 71: 137-144, 1992[Abstract/Free Full Text].

24. Okamoto, H, Hudetz AG, Roman RJ, Bosnjak ZJ, and Kampine JP. Neuronal NOS-derived NO plays permissive role in cerebral blood flow response to hypercapnia. Am J Physiol Heart Circ Physiol 272: H559-H566, 1997[Abstract/Free Full Text].

25. Parfenova, H, Massie V, and Leffler CW. Developmental changes in endothelium-derived vasorelaxant factors in cerebral circulation. Am J Physiol Heart Circ Physiol 278: H780-H788, 2000[Abstract/Free Full Text].

26. Parkinson, PA, Parfenova H, and Leffler CW. Phospholipase C activation by prostacyclin receptor agonist in cerebral microvascular smooth muscle cells. Proc Soc Exp Biol Med 223: 53-58, 2000[Abstract/Free Full Text].

27. Pearce, WJ, Hull AD, Long DM, and Longo LD. Developmental changes in ovine cerebral artery composition and reactivity. Am J Physiol Regulatory Integrative Comp Physiol 261: R458-R465, 1991[Abstract/Free Full Text].

28. Pelligrino, DA, Wang Q, Koenig HM, and Albrecht RF. Role of nitric oxide, adenosine, N-methyl-D-aspartate receptors, and neuronal activation in hypoxia-induced pial arteriolar dilation in rats. Brain Res 704: 61-70, 1995[ISI][Medline].

29. Puybasset, L, Bea ML, Ghaleh B, Giudicelli JF, and Berdeaux A. Coronary and systemic hemodynamic effects of sustained inhibition of nitric oxide synthesis in conscious dogs. Evidence for cross talk between nitric oxide and cyclooxygenase in coronary vessels. Circ Res 79: 343-357, 1996[Abstract/Free Full Text].

30. Rama, GP, Parfenova H, and Leffler CW. Protein kinase Cs and tyrosine kinases in permissive action of prostacyclin on cerebrovascular regulation in newborn pigs. Pediatr Res 41: 83-89, 1997[ISI][Medline].

31. Renz, H, Gong JH, Schmidt A, Nain M, and Gemsa D. Release of tumor necrosis factor- $alpha$ from macrophages. Enhancement and suppression are dose-dependently regulated by prostaglandin E₂ and cyclic nucleotides. J Immunol 141: 2388-2393, 1988[Abstract].

32. Salvemini, D, Settle SL, Masferrer JL, Seibert K, Currie MG, and Needleman P. Regulation of prostaglandin production by nitric oxide: an in vivo analysis. Br J Pharmacol 114: 1171-1178, 1995[ISI][Medline].

33. Smith, WL, Garavito RM, and DeWitt DL. Prostaglandin endoperoxide H synthases (cyclooxygenases)-1 and -2. J Biol Chem 271: 33157-33160, 1996[Free Full Text].

34. Son, MT, and Zuckerman SL. Chronic inhibition of prostanoid generation produces an increased role of nitric oxide in the newborn (Abstract). Pediatr Res 41: 39A, 1997.

35. Thompson, LP, and Weiner CP. Acetylcholine relaxation of renal artery and nitric oxide synthase activity of renal cortex increase with fetal and postnatal age. Pediatr Res 40: 192-197, 1996[ISI][Medline].

36. Wang, Q, Pelligrino DA, Baughman VL, Koenig HM, and Albrecht RF. The role of neuronal nitric oxide synthase in regulation of cerebral blood flow in normocapnia and hypercapnia in rats. J Cereb Blood Flow Metab 15: 774-778, 1995[ISI][Medline].

37. Willis, AP, and Leffler CW. NO and prostanoids: age dependence of hypercapnia and histamine-induced dilations of pig pial arterioles. Am J Physiol Heart Circ Physiol 277: H299-H307, 1999[Abstract/Free Full Text].

38. Yang, G, and Iadecola C. Obligatory role of NO in glutamate-dependent hyperemia evoked from cerebellar parallel fibers. Am J Physiol Regulatory Integrative Comp Physiol 272: R1155-R1161, 1997[Abstract/Free Full Text].

39. Zuckerman, SL, Armstead WM, Hsu P, Shibata M, and Leffler CW. Age dependence of cerebrovascular response mechanisms in domestic pigs. Am J Physiol Heart Circ Physiol 271: H535-H540, 1996[Abstract/Free Full Text].

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