INTRODUCTION

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THE AUTOREGULATION of cerebral blood flow has been explained in connection with metabolic and myogenic mechanisms involved in cerebral microcirculation (3, 17). Edwards et al. (5) suggested that calcitonin gene-related peptide (CGRP) stimulated adenyl cyclase activity in the small parenchymal cerebral arterioles in vitro. Recently, the autoregulatory vasodilation of rat pial arteries in response to hypotension has been demonstrated to be mediated by CGRP, which is released from the perivascular sensory fibers (8); furthermore, the CGRP-induced vasodilation is mediated by the formation of cAMP via activation of CGRP₁ receptors (9).

The relationship between adenosine concentration and oxygen supply was documented in rat brain, in that adenosine is a mediator of the metabolic regulation of cerebral blood flow during normoxia and hypoxia (1, 19). A number of studies have reported that adenosine serves an important role in vascular biology through multiple actions that are mediated primarily by adenosine A₁ and A₂ receptors. Ngai and Winn (16) reported that the dilator response of intracerebral arterioles to adenosine was predominantly mediated by the A₂ receptors.

On the other hand, Mi and Jackson (13) proposed a metabolic cAMP-adenosine pathway, in that perfusion with cAMP significantly increased AMP and adenosine. Reportedly, cAMP is transported to the extracellular space when it is formed intracellularly (2) and then converted to AMP and, hence, to adenosine by the enzymes endo- and ectophosphodiesterase (PDE) and endo- and ecto-5'-nucleotidase, respectively (13). However, whether the cAMP-adenosine metabolic pathway is implicated in the cerebral vasodilation is uncertain.

The purpose of the present study was to provide functional evidence in support of the working hypothesis that CGRP receptor-coupled cAMP production may be implicated in the autoregulatory vasodilation in response to acute hypotension. Thus experiments were designed to evaluate whether adenosine was formed by means of the cAMP-adenosine pathway, which would contribute to the autoregulatory vasodilation of the pial microvessels in response to hypotension. For this purpose, we first determined the vasodilating effects of cAMP and adenosine when the microvessels were pretreated with the A₁-receptor antagonist 8-cyclopentyltheophylline (CPT) and the A₂ receptor antagonist 3,7-dimethyl-1-propargylxanthine (DMPX). Second, we estimated the effects of the inhibitors of PDE and 5'-nucleotidase on the vasodilation induced by cAMP or hypotension. Thereafter, we measured the releases of AMP, adenosine, and inosine when the cortical surface was suffused with artificial cerebrospinal fluid (CSF) containing cAMP in the absence and presence of enzyme inhibitors.

	METHODS

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Preparation of animals. Male Sprague-Dawley rats (250-300 g) were anesthetized with urethan (1 g/kg ip) and placed on a heating pad to maintain a constant body (rectal) temperature (37 ± 0.5°C). After a tracheostomy, the trachea was cannulated, and the rat was mechanically ventilated with room air by a respirator (model 683, Harvard) after immobilization with 5 mg/kg gallamine triethiodide. Catheters were placed in the carotid artery for measurement of systemic arterial blood pressure (Statham P23 D pressure transducer) and in the femoral artery for sampling of arterial blood. Arterial blood was collected before and after installation of a cranial window for blood gas and pH determination (STAT Profile 3, Nova Biomedicals). The mean arterial blood gases and pH were within normal limits as follows: pH 7.39 ± 0.02, arterial PCO₂ 34.7 ± 1.8 mmHg, arterial PO₂ 95.0 ± 1.2 mmHg. Rectal temperature was kept constant with a heating pad.

Measurement of vessel diameter. Pial microvessels were visualized through an implanted closed cranial window (8). Briefly, the head was fixed in the prone position with a stereotaxic apparatus (Stoelting, Wood Dale, IL), and a square (5 × 5 mm²) craniotomy was made over the right parietal cortex. The dura was carefully resected. Pial precapillary microvessels [64.0 ± 2.5 µm (large) and 31.0 ± 2.3 µm (small) arterioles] were visualized through the implanted cranial window, where prewarmed artificial CSF (37°C) saturated with 95% O₂-5% CO₂ was constantly perfused at 0.3 ml/min. Cerebral microvessels were allowed to equilibrate for 60 min after installation of the cranial window. The image of the pial vessels was captured with a CCD video camera (model VDC 3900, Sanyo) through a stereomicroscope (model SMZ-2T, Nikon) and fed to a television monitor for direct observation, and the caliber was measured using a width analyzer (model C3161, Hamamatsu Photonics). The composition (in mmol/l) of the artificial CSF was as follows: 132 NaCl, 2.9 KCl, 1.4 MgCl₂, 24.6 NaHCO₃, 1.2 CaCl₂, 6.7 urea, and 3.7 D-glucose (pH 7.4). The intracranial pressure was maintained constant at 5-6 mmHg throughout the experiment by adjustment of the height of the free end of the plastic tubing, which was connected to the outlet of the window. In each rat, only one arteriole was observed under the window.

Protocol of in vivo experiments. To examine the vasodilating responses of the resting pial arteries to cAMP and adenosine, the cortical surface was suffused with artificial CSF containing cAMP (1-100 µmol/l) or adenosine (0.01-10 µmol/l). The inhibitory effects of CPT (1 µmol/l) and DMPX (1 µmol/l) were observed on the cAMP- and adenosine-induced vasodilation, respectively. The inhibitors were applied beginning 30 min before suffusion of cAMP or adenosine. Furthermore, we examined initially the normal autoregulatory vasodilator function of the pial artery to a stepwise hypotension and its reverse to infusion of blood from the reservoir when the cortical surface was suffused with artificial CSF containing vehicle. Thereafter, we retested the autoregulatory responses when the vessels were pretreated with CPT or DMPX. Stepwise hypotension was induced by controlled withdrawal of blood into the reservoir. The decreased blood pressure at each step was maintained for ~2 min, and vessel diameter was measured during the last minute. Alterations in pial arterial diameter and blood pressure were expressed as percent changes in baseline diameter and blood pressure.

Analysis of adenine nucleoside. AMP, adenosine, and inosine levels in the suffusate were analyzed with an HPLC system. Briefly, in the first experimental series, the cortical surface was suffused with artificial CSF while vasodilation was monitored. After the suffusate exiting the cranial window for 2 min was collected as a basal sample, cAMP was added to the artificial CSF to a final concentration of 100 µmol/l and the suffusate was collected into small polycarbonate tubes at 1, 3, 5, 10, 15, 20, and 30 min of suffusion. A second experimental series was conducted in the same fashion, with addition of 3-isobutyl-1-methylxanthine (IBMX), ,-methylene-adenosine 5'-diphosphate (AMP-CP), or 1,3-dipropyl-8-p-sulfophenylxanthine (DPSPX), inhibitors of enzymatic metabolism, 20 min before application of cAMP.

Drugs. Adenosine, cAMP sodium salt (cAMP), N⁶,2'-O-dibutyryl-cAMP sodium salt (DBcAMP), 8-bromo-cAMP sodium salt (8-BrcAMP), AMP-CP sodium salt (AMP-CP), and IBMX were purchased from Sigma-Aldrich Korea. CPT, DMPX, and DPSPX were obtained from Research Biochemicals International.

Statistical analysis. Values are means ± SE. Results were statistically evaluated by Student's t-test for the differences between the corresponding data of vehicle- and inhibitor-treated groups and between the slopes of linear regression lines, in which changes in pial arterial diameter were plotted as a function of changes in mean arterial blood pressure. ANOVA was performed with repeated measures followed by Tukey's multiple comparison test for the differences in the time-arterial diameter relationship between groups. P < 0.05 was accepted as statistically significant.

	RESULTS

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Under control conditions, mean arterial blood pressure was within the normal range (105.5 ± 2.4 mmHg, n = 47). The basal pial arterial diameters were 64.0 ± 2.5 and 31.0 ± 2.3 µm for the larger and smaller arterioles, respectively; these values remained constant throughout the experiment, unless there was bleeding or an infusion of blood.

Differences in the vasodilating effect of cAMP from cAMP analogs. The vasodilating effect of cAMP was compared with DBcAMP and 8-BrcAMP (Fig. 1). DBcAMP and 8-BrcAMP exerted weak vasodilation with relatively low maximal dilation at 100 µmol/l. In contrast, cAMP showed a sustained vasodilation in a concentration-dependent manner. The agonist concentrations required to cause 25% of observed maximum dilations (EC₂₅) in the larger and smaller arterioles for cAMP-induced vasodilation were 43.0 ± 21.2 and 8.2 ± 3.2 µmol/l, respectively, with maximal dilation of 54.0 ± 6.1 and 76.9 ± 9.1% of the basal diameters, respectively. These findings were not significantly different between the larger and smaller arterioles.

View larger version (31K): [in this window] [in a new window]   Fig. 1.   Percent changes in diameter in response to cAMP, dibutyryl cAMP, and 8-bromo-cAMP of larger and smaller arterioles. Values are means ± SE.

Effects of adenosine receptor antagonists. Suffusion of the cortical surface with artificial CSF containing cAMP (1, 10, or 100 µmol/l) or adenosine (0.01, 0.1, 1, or 10 µmol/l) caused a sustained concentration-dependent vasodilation (Fig. 2).

View larger version (29K): [in this window] [in a new window]   Fig. 2.   Percent changes in diameter of smaller pial arterioles in response to cAMP (1-100 µmol/l) and adenosine (0.01-10 µmol/l) in absence and presence of 8-cyclopentyltheophylline (CPT). Cortical surface was suffused with artificial cerebrospinal fluid (CSF) containing 1 µmol/l CPT 30 min before and throughout experiment. Values are means ± SE from 4 experiments.

View larger version (27K): [in this window] [in a new window]   Fig. 3.   Percent changes in diameter of smaller pial arterioles in response to cAMP (1-100 µmol/l) and adenosine (0.01-10 µmol/l) in absence and presence of 3,7-dimethyl-1-propargylxanthine (DMPX). Cortical surface was suffused with artificial CSF containing 1 µmol/l DMPX 30 min before and throughout experiment. Values are means ± SE from 6 experiments.

Effects of enzyme inhibitors on cAMP-induced vasodilation. We observed the vasodilating effect of cAMP when the arterioles were pretreated with IBMX (3 µmol/l), an inhibitor of endo- and ecto-PDE, DPSPX (100 µmol/l), an inhibitor of ecto-5'-PDE, and AMP-CP (100 µmol/l), an inhibitor of ecto-5'-nucleotidase (Fig. 4). IBMX at >10 µmol/l caused vasodilation. Thus in the present study we employed IBMX at 3 µmol/l to inhibit PDE. Pretreatment with IBMX, DPSPX, or AMP-CP exerted a potent inhibitory effect on the cAMP-induced vasodilation of the pial arterioles, suggesting that endo- and ecto-PDE, and also ecto-5'-nucleotidase, are involved in the cAMP hydrolysis turnover.

View larger version (23K): [in this window] [in a new window]   Fig. 4.   Percent changes in diameter of smaller pial arterioles in response to cAMP (1-100 µmol/l) in absence and presence of 3-isobutyl-1-methylxanthine (IBMX, 3 µmol/l, n = 5), 1,3-dipropyl-8-sulfophenylxanthine (DPSPX, 100 µmol/l, n = 4), and ,-methylene-adenosine 5'-diphosphate (AMP-CP, 100 µmol/l, n = 4). Cortical surface was suffused with artificial CSF containing each inhibitor 30 min before and throughout experiment. Values are means ± SE.

Alterations in autoregulatory responses. The alteration in autoregulatory vasodilation in response to a stepwise hypotension was observed after treatment with the adenosine A₁- and A₂-receptor antagonists CPT and DMPX (Figs. 5 and 6). In the vehicle group the pial arterial diameters increased during stepwise hypotension and quickly decreased on recovery of the arterial pressure. Changes in pial arterial diameter were plotted as a function of changes in blood pressure. After pretreatment with 1 µmol/l DMPX (Fig. 6), but not with 1 µmol/l CPT (Fig. 5), the autoregulatory vasodilator and vasoconstrictor responses of the pial arterioles were markedly suppressed. The slopes for the vasodilation phase (vehicle group, 1.51 ± 0.18) were changed to 0.48 ± 0.15 (P < 0.01) on pretreatment with 1 µmol/l DMPX (Table 2). Furthermore, with IBMX (3 µmol/l) and AMP-CP (100 µmol/l) pretreatment, the slopes of vasodilator and vasoconstrictor responses to hypotension and to reverse of blood pressure were significantly less steep (Fig. 7, Table 2).

View larger version (21K): [in this window] [in a new window]   Fig. 5.   Autoregulatory vasodilation and vasoconstriction in response to stepwise hypotension after pretreatment with CPT (1 µmol/l) in comparison with vehicle. Changes in pial arterial diameter were plotted as a function of changes in mean arterial blood pressure (MABP). All slopes of regression lines showed statistical significance. No difference was observed between vehicle- and CPT-treated groups.

View larger version (22K): [in this window] [in a new window]   Fig. 6.   Autoregulatory vasodilation and vasoconstriction without and with DMPX (1 µmol/l). After autoregulation was confirmed, cortical surface was suffused with artificial CSF containing DMPX (1 µmol/l, n = 7) 30 min before and throughout stepwise hypotension. DMPX significantly attenuated autoregulatory vasodilation and vasoconstriction. Significant difference (P < 0.05) was identified between blood pressure-diameter relationship of vehicle- and DMPX-treated groups by 2-way repeated-measures ANOVA.

View larger version (21K): [in this window] [in a new window]   Fig. 7.   Alterations in autoregulatory responses after pretreatment with IBMX (3 µmol/l, n = 7). Suffusion with IBMX markedly attenuated autoregulatory responses. Significant difference (P < 0.05) was identified between blood pressure-diameter relationship of vehicle- and IBMX-treated groups by 2-way repeated-measures ANOVA.

cAMP metabolism in the suffusate. When the artificial CSF containing 100 µmol/l cAMP was suffused over the cortical surface, the levels of AMP, adenosine, and inosine increased significantly with time: 7.7 ± 0.5, 1.1 ± 0.1, and 0.7 ± 0.4 µmol/l, respectively, at 5 min (Fig. 8). In the group not treated with cAMP, these nucleosides were not detectable.

View larger version (20K): [in this window] [in a new window]   Fig. 8.   Time course of metabolism of exogenous cAMP (100 µmol/l) to AMP, adenosine, and inosine during suffusion on cortical surface. Formation of AMP, adenosine, and inosine in suffusate was analyzed by HPLC, their concentrations were quantified by calculating area under peak, and a substantial amount of each substance was calculated from a standard curve of respective substance. Values are means ± SE of 8 experiments. * P < 0.05; ** P < 0.01 compared with time 0. Statistical analysis was performed with ANOVA (P < 0.05).

View larger version (23K): [in this window] [in a new window]   Fig. 9.   Metabolism of cAMP (100 µmol/l) to AMP, adenosine, and inosine during suffusion on cortical surface in absence and presence of IBMX (100 µmol/l), DPSPX (100 µmol/l), and AMP-CP (100 µmol/l). AMP, adenosine, and inosine were measured in 5-min suffusate. Vehicle, cortical surface suffused with cAMP alone; ND, not detectable. Values are means ± SE of 4 experiments. * P < 0.05; ** P < 0.01 vs. vehicle.

	DISCUSSION

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The major findings of this study are as follows: 1) cAMP, but not DBcAMP and 8-BrcAMP, showed a potent vasodilation; 2) vasodilation induced by adenosine or cAMP and vasodilation in response to hypotension were markedly attenuated when the cortical surface was suffused with artificial CSF containing DMPX, an A₂-receptor antagonist, but not by CPT, an A₁-receptor antagonist; 3) when the arteriole was pretreated with IBMX (3 µmol/l, an inhibitor of endo- and ecto-PDE), DPSPX (100 µmol/l, an inhibitor of ecto-5'-PDE), and AMP-CP (100 µmol/l, an inhibitor of ecto-5'-nucleotidase), the vasodilating effect of cAMP (1-100 µmol/l) was significantly decreased; 4) the autoregulatory vasodilation and release of AMP and adenosine from the suffusate containing cAMP were significantly decreased by IBMX, DPSPX, and AMP-CP, inhibitors of enzymatic metabolism of cAMP.

In the present study, DBcAMP and 8-BrcAMP showed weak vasodilation in comparison with cAMP, although their hydrolytic stability and membrane permeability were high in comparison to cAMP. Consistent with the report of Johnson et al. (11), suffusion of cAMP provided large amounts of metabolites, such as adenosine. Rosenblum (18) demonstrated the existence of an adenyl cyclase-cAMP system in mice for dilating cerebral arterioles, suggesting that the cerebral surface arterioles contain the enzyme system for producing the dilator. However, the cAMP analogs DBcAMP and 8-BrcAMP did not produce the metabolites. Nevertheless, the nonmetabolizable analogs of cAMP exerted vasodilating effects at 100 µmol/l. This fact may indicate an involvement of a mechanism other than adenosine-mediated cascade. Clarification requires further study.

Kalaria and Harik (12) demonstrated with specific tritiated ligands for A₁ (cyclohexyladenosine) and A₂ receptors (5'-N-ethylcarboxamide adenosine) that human pial vessels have specific high-affinity 5'-N-ethylcarboxamide adenosine binding to A₂ receptors and few, if any, A₁ receptors. In agreement with their results, our study showed that CPT, an A₁ receptor antagonist, did not exert any inhibitory effect on the autoregulatory vasodilation in response to hypotension or on the cAMP-induced vasodilation.

Jackson (10) and Mi and Jackson (13) recently proposed the cAMP-adenosine pathway for adenosine production in vascular smooth muscle cells. This pathway begins with activation of adenyl cyclase. Within the cell, the cAMP produced is metabolized to AMP by the catalyzing enzyme cytosolic PDE, and AMP is metabolized to adenosine by cytosolic 5'-nucleotidase. Then the adenosine is transported to the extracellular space by way of facilitated transport (13). The egress of cAMP from metazoan cells has been demonstrated on stimulation of adenyl cyclase (2). Moreover, vascular smooth muscle cells have an abundant ecto-5'-nucleotidase, which efficiently metabolizes AMP to adenosine (6). The ecto-5'-nucleotidase is tethered to the extracellular face of the plasma membrane via a lipid-sugar linkage (14). In the present in vivo study, there is no way to measure the intracellular adenosine concentration. Instead, in the HPLC study, AMP, adenosine, and inosine were produced by suffusion of cAMP (100 µmol/l) over the cortical surface. These metabolites were significantly increased with time, implying a viable metabolic cAMP-adenosine pathway in the extracellular space of the cortical surface. Other aforementioned reports, together with our findings that IBMX and DPSPX significantly inhibited the metabolism of cAMP to AMP and, hence, to adenosine, further support the speculation that the cAMP-adenosine pathway may play an important role in mediating vasodilation in response to hypotension. The AMP metabolism to adenosine was completely inhibited by AMP-CP, whereas AMP secretion remained unchanged. These findings were consistent with the results of Dubey et al. (4), who observed an inhibitory effect of cAMP-derived adenosine on vascular smooth muscle cell growth. Therefore, it can be inferred that if a relatively modest increase in cAMP production occurs in the pial artery, a significant amount of adenosine can be formed by the intracellular and extracellular enzyme reactions.

Recently, we reported in vivo evidence that the autoregulatory vasodilation of rat pial arterioles in response to a stepwise hypotension is mediated by CGRP, which is released from the perivascular sensory fibers (8), and that the CGRP-induced cerebral vasodilation is mediated by the formation of cAMP via activation of CGRP₁ receptors (9). These results are consistent with the in vitro results of Edwards et al. (5), who showed that CGRP stimulates adenylate cyclase in the cerebral arterioles. Under the hypothesis that CGRP receptor-coupled cAMP production is implicated in the autoregulatory vasodilation in response to acute hypotension, it is speculated that adenosine may be formed by means of the cAMP-adenosine pathway.

Winn et al. (20) described the role of adenosine in autoregulation of cerebral blood flow as a metabolic factor, in that brain adenosine concentrations are rapidly increased within 5 s of the onset of systemic hypotension and parallel the changes in pial vessel diameter. In line with this report, the autoregulatory vasodilator adjustment in response to hypotension was significantly suppressed by pretreatment with the A₂-receptor antagonist DMPX and the inhibitors of cAMP metabolism IBMX, DPSPX, and AMP-CP. These findings provide strong evidence to support the hypothesis that the extracellular cAMP-adenosine pathway may be implicated in the CGRP-induced neurogenic vasodilation of the pial arteries during acute hypotension. In the present study the role of inosine, however, remained unexplained. Ngai et al. (15) reported that inosine alone does not affect pial vessel diameter, but it potentiates the response of pial arterioles to exogenous adenosine as an adenosine uptake inhibitor.

The extracellular concentration of adenosine in the rat brain measured by means of brain dialysis (22) and the freeze-blow technique (21) was reported to be 1-2 µM. In our study, vasodilation of the pial arterioles was elicited by 0.01-0.1 µmol/l adenosine under normoxic conditions. Thus the concentrations used in this study appear to be lower than those measured in the parenchymal tissue. However, an important issue is whether concentrations of cAMP in the interstitial fluid surrounding pial arterioles are high enough to support adenosine formation. Even though interstitial levels of cAMP on the cortical surface are determined by dialysis or the freeze-blow technique, it is not easy to equate the interstitial levels with the concentrations of cAMP achieved by formation and transport into the extracellular sites surrounding the arterioles.

The present in vivo study does not allow identification of the cell types involved in the metabolism of cAMP to adenosine. Ecto-5'-nucleotidase was reported to be present in abundance in cultured aortic endothelial cells and aortic smooth muscle cells (6, 7). Nevertheless, it is not clear what cell type contributes to the conversion of cAMP to adenosine. It seems impossible to judge how many fractions of cAMP endogenously are produced, actually gain to access to the enzyme system of the cAMP-adenosine pathway, and are efficiently converted to adenosine.

It is suggested that the cAMP-adenosine pathway is implicated in the production of adenosine in the rat pial artery. Thus it is concluded that the contribution of the cAMP-adenosine pathway may be important in the regulation of cerebral vasodilation in response to hypotension. Further study is required to identify the cascade of the CGRP receptor-coupled cAMP production and its metabolism to adenosine in the cerebral arterioles.