Superoxide-dependent cerebrovascular effects of homocysteine

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Superoxide-dependent cerebrovascular effects of homocysteine

Fangyi Zhang¹, Arne Slungaard², Gregory M. Vercellotti², and Costantino Iadecola¹

¹ Laboratory of Cerebrovascular Biology and Stroke, Department of Neurology, and ² Department of Medicine, University of Minnesota Medical School, Minneapolis, Minnesota 55455

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

Recent evidence indicates that elevated plasma levels of homocysteine are a risk factor for ischemic cerebrovascular diseases.However, little is known about cerebrovascular effects of homocysteine.Homocysteine could impair cerebrovascular function by metal-catalyzedproduction of activated oxygen species. We studied whether homocysteine,in the presence of Cu²⁺, alters reactivity of cerebral circulation and, if so, whetherthis effect depends on O₂ generation. In halothane-anesthetizedrats the parietal cortex was exposed and superfused with Ringersolution. Cerebrocortical blood flow (CBF) was monitored by alaser-Doppler probe. With Ringer solution superfusion, CBF increasedwith hypercapnia (+134 ± 7%; PCO₂ = 50-60 mmHg) and topicalapplication of 10 µM ACh (+35 ± 3%), the NO donor S-nitroso-N-acetylpenicillamine(SNAP, 500 µM; +66 ± 6%), or 1 mM papaverine (+100 ± 6%; n = 5).Superfusion with 40 µM Cu²⁺ alone did not perturb resting CBF or responses to hypercapnia,ACh, SNAP, or papaverine (P > 0.05, n = 5). However, superfusionof homocysteine-Cu²⁺ reduced resting CBF ( $-$ 28 ± 4%) and attenuated (P < 0.05) responsesto hypercapnia ( $-$ 31 ± 9%), ACh ( $-$ 73 ± 6%), or SNAP ( $-$ 48 ± 4%),but not papaverine. The effect was observed only at 1 mM homocysteine.Cerebrovascular effects of homocysteine-Cu²⁺ were prevented by coadministration of superoxide dismutase (SOD;1,000 U/ml; n = 5). SOD alone did not affect resting CBF or CBFreactivity (n = 5). The observation that homocysteine-Cu²⁺ attenuates the response to hypercapnia, ACh, and SNAP, but notthe NO-independent vasodilator papaverine, suggests that homocysteine-Cu²⁺ selectively impairs NO-related cerebrovascular responses. Thefact that SOD prevents such impairment indicates that the effectof homocysteine is O₂ dependent. The data supportthe conclusion that O₂, generated by the reactionof homocysteine with Cu²⁺, inhibits NO-related cerebrovascular responses by scavengingNO, perhaps through peroxynitrite formation. O₂-mediatedscavenging of NO might be one of the mechanisms by which hyperhomocysteinemiapredisposes to cerebrovascular diseases.

rat; cerebral circulation; nitric oxide; vasodilation

	INTRODUCTION

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ELEVATED PLASMA LEVELS of homocysteine are an independent risk factor for atherosclerosis and are associated with a varietyof thromboembolic complications (see Refs. 24 and 31 for review).Recent case-control studies suggest that hyperhomocysteinemiais also a risk factor for ischemic stroke (3). Patients withinherited cystathionine $beta$ -synthase deficiency exhibit markedlyelevated levels of plasma homocysteine (200-250 µM) and have anincreased incidence of ischemic strokes (22). More recently,it has been suggested that cerebrovascular diseases in the generalpopulation are associated with moderate elevation of plasma homocysteine(10-50 µM) (2, 4, 7, 32). Because plasma levels ofhomocysteine can be lowered by administration of vitamins, theseobservations raise the possibility that hyperhomocysteinemia isa treatable risk factor for stroke in the general population (3).

The mechanisms by which hyperhomocysteinemia leads to an increased incidence of ischemic stroke have not been fully elucidated.Whereas hyperhomocysteinemia-induced atherosclerosis and hypercoagulabilityare likely to play an important role (12, 13, 28, 33; see Ref.24 for review), homocysteine could also impair compensatoryvasodilatory mechanisms and worsen the outcome of cerebral ischemia.In support of this hypothesis is the observation that vascularreactivity to ACh, a response most likely mediated by releaseof endothelial NO, is reduced in hyperhomocysteinemic monkeys(19). A potential mechanism for the vascular effects of homocysteineincludes autoxidation of the thiol group, a reaction that producesthe reactive oxygen species superoxide anion (6, 23). Superoxideanion could scavenge NO via rapid formation of peroxynitrite (8),thereby reducing the amount of NO available for vasodilation.

In the present study we sought to test the hypothesis that homocysteine impairs NO-related cerebrovascular responses throughsuperoxide anion production. We found that homocysteine, in thepresence of Cu²⁺, reduces resting cerebral blood flow (CBF) and attenuates theincreases in CBF produced by ACh, hypercapnia, and S-nitroso-N-acetylpenicillamine(SNAP), responses that depend on NO. In contrast, the increasein CBF produced by papaverine, a vasodilator that acts independentlyof NO, is not affected. The cerebrovascular actions of homocysteineare prevented by treatment with the superoxide anion scavengersuperoxide dismutase (SOD). The data are consistent with the hypothesisthat high concentrations of homocysteine selectively impair cerebrovascularresponses mediated by NO via superoxide-dependent mechanisms.Homocysteine-induced loss of vascular reactivity may be a factorcontributing to the increased incidence of ischemic injury inpatients with hyperhomocysteinemia.

	METHODS

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Methods for superfusion of drugs on the cerebral cortex, induction of hypercapnia, monitoring of CBF by laser-Doppler flowmetry,and the NO synthase (NOS) assay have been described previously(14, 16) and are summarized below.

General Surgical Procedures

Studies were performed in 25 male Sprague-Dawley rats (Sasco, Omaha, NE) weighing 300-380 g. Rats were anesthetized with 5%halothane in 100% oxygen. After induction of anesthesia the concentrationof halothane was reduced to 1-2%. Cannulas were inserted in theleft femoral artery and in the trachea. Animals were then placedon a stereotaxic frame (model 1404, Kopf Instruments, Tujunga,CA) and artificially ventilated with a nitrogen-oxygen mixtureby a mechanical ventilator (model 638, Harvard Apparatus, S. Natick,MA). The proportion of oxygen in the mixture was adjusted to maintainarterial PO₂ at ~150 mmHg [153 ± 23 (SD) mmHg]. Bodytemperature was maintained at 37 ± 0.5°C by use of a heating lampcontrolled by a rectal probe (model 73A-TA, Yellow Springs Instrument,Yellow Springs, OH). The arterial catheter was used for bloodsampling and continuous recording of arterial pressure and heartrate on a chart recorder (model 716P, Grass, Quincy, MA). ArterialPCO₂ (Pa_CO₂), PO₂, and pH were measured at multipletimes on 50-100 µl of blood with use of a blood-gas analyzer (model178, Ciba-Corning, Medfield, MA). After completion of the surgicalprocedures the halothane concentration was reduced to 1%. Thelevel of anesthesia was tested by verifying the absence of cornealreflexes and motor responses to tail pinch. Rats were then paralyzedwith tubocurarine. After paralysis the depth of anesthesia wasmonitored by testing the cardiovascular responses to tail pinchand by the pattern of the electrocorticogram (16). The electrocorticogramwas recorded monopolarly using a metal screw inserted throughthe bone at a site near the cranial window. As described in detailelsewhere (14, 16), a 3 × 3-mm cranial window was drilledat a site 2-3 mm lateral and 1-2 mm rostral to bregma. The durawas carefully removed, and the craniotomy site was continuouslysuperfused at a rate of 0.33 ml/min with Ringer solution warmedto 37°C and aerated with 95% oxygen-5% carbon dioxide (pH 7.3-7.4).

Monitoring of CBF by Laser-Doppler Flowmetry

Laser-Doppler flowmetry was performed using a Vasamedic BPM403 instrument, the output of which was displayed on a chart recorder(14, 16). The probe (tip 0.8 mm) was mounted on a micromanipulatorand placed ~0.5 mm above the pial surface within the cranial window.Probe position and reactivity of the preparation were tested ateach site by determining the cerebrovascular reactivity to changesin Pa_CO₂. Once a suitable placement was obtained, the probe wasleft at that site for the duration of the experiment.

NOS Assay

Methods for measuring brain Ca²⁺-dependent NOS catalytic activity by the isotopic conversion assay of Bredt and Snyder havebeen described in detail previously (16) and are briefly summarized.The entire forebrain of four rats was homogenized in 20 mM HEPEScontaining 0.5 mM EGTA, 1 mM dithiothreitol, and 0.32 M sucrose(Polytron/PT3000, Brinkmann). The homogenate was centrifuged at20,000 rpm for 15 min, and triplicates of aliquots of the supernatant(150 µg protein) were incubated for 45 min (37°C) with a buffercontaining 20 mM HEPES, 0.5 mM EGTA, 1 mM dithiothreitol, 0.32M sucrose, 0.5 mM Ca²⁺ (1 µM free Ca²⁺), 200 µM NADPH, 1 µM L-arginine, and 1 µCi/ml L-[³H]arginine. The reaction was stopped by addition of 2 ml of 20mM cold HEPES containing 2 mM EDTA (pH 5.5). Samples were appliedto Dowex AG50W-X8 (Na⁺ form) columns to remove L-[³H]arginine. Columns were then washed with 2 ml of water, and L-[³H]citrulline was quantified in the flow-through fraction by useof a liquid scintillation spectrophotometer (model LS 6000, Beckman).The level of L-[³H]citrulline was computed after subtraction of the blank value,which represents nonspecific radioactivity in the absence of enzymeactivity. In studies in which the effect of homocysteine on NOSactivity was tested, homocysteine (0, 1, 10, 100, 1,000 µM) wasadded to aliquots of homogenate before the 45-min incubation period.Aliquots run in parallel were treated with comparable concentrationsof the NOS inhibitor N-monomethyl-L-arginine. Enzyme inhibitionwas expressed as a percentage of NOS catalytic activity of vehicle-treatedaliquots.

Experimental Protocol

The cranial window was superfused with normal Ringer solution, and blood gases were adjusted (Table 1). The laser-Dopplerprobe was positioned on the cerebral cortex for continuous monitoringof CBF. Experiments commenced once arterial pressure, blood gases,and CBF were in a steady state.

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Table 1. Arterial pressure and blood gases

Effect of homocysteine on resting CBF. The cranial window was superfused with Ringer solution for 30 min. The superfusion solution was sequentially changed to 1)Ringer solution containing 40 µM Cu²⁺ for 60 min, 2) Ringer solution containing 40 µM Cu²⁺ and 1 mM homocysteine for 120 min, and 3) normal Ringer solutionfor 90 min (Ringer 2; Fig. 1). The changes in CBF associated withthese treatments were continuously recorded. These experimentswere performed in six rats.

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Fig. 1. Effect of Cu²⁺-homocysteine on resting cerebral blood flow (CBF). Superfusion with Cu²⁺ alone (40 µM) does not affect resting CBF, whereas Cu²⁺ in conjunction with 1 mM homocysteine (Cu²⁺/HC) reduces CBF (P < 0.05 by ANOVA and Tukey's test). Effect is reversible because, after Cu²⁺-homocysteine, superfusion with Ringer (Ringer 2) reestablishes basal CBF (P > 0.05 vs. Ringer 1).

Effect of homocysteine on the increase in CBF produced by ACh, hypercapnia, SNAP, or papaverine. The increase in CBF produced by hypercapnia, the NO-dependent vasodilator ACh (10 µM), the NO donor SNAP (500 µM), or theNO-independent vasodilator papaverine (1 mM) was studied. Hypercapnia(Pa_CO₂ = 50-60 mmHg) was produced by adding carbon dioxide tothe circuit of the ventilator. The elevation in Pa_CO₂ was maintaineduntil the resulting flow increase was in a steady state (usually3 min) (14, 16). Agents were dissolved in Ringer solutionand topically superfused until the CBF elevation reached a steadystate. Concentrations yielding ~50% of maximal response were used.Similarly, we used levels of hypercapnia (PCO₂ = 50-60mmHg) that produce ~50% of the maximal CBF elevation (17). CBFresponses to hypercapnia, ACh, SNAP, and papaverine were testedin random sequence during superfusion with normal Ringer solution(Ringer 1; Fig. 1), 40 µM Cu²⁺, or Cu²⁺-homocysteine (1 mM). Responses were tested 60-90 min after theCu²⁺-homocysteine superfusion was started. The time interval betweenresponses was 10-15 min. At the end of the superfusion with Cu²⁺-homocysteine, the solution was changed to normal Ringer (Ringer2), and responses were tested again 60 min later. These experimentswere performed in five rats.

Dose-response relationships. CBF responses to hypercapnia, ACh, and SNAP were tested during superfusion with normal Ringer solution or Ringer solutioncontaining 40 µM Cu²⁺ and increasing concentrations of homocysteine (100, 500, 1,000µM). Each concentration was applied for 60-90 min before the responseswere tested. The time interval between responses was 10-15 min.These experiments were performed in five rats.

Effect of SOD on homocysteine-induced attenuation of vasodilator responses. Responses to hypercapnia, ACh, and SNAP were tested in random sequence during superfusion with normal Ringer solution, Ringersolution containing 1,000 U/ml of SOD, or Ringer solution containing40 µM Cu²⁺, SOD (1,000 U/ml), and 1 mM homocysteine. Vasodilator responseswere tested after each solution was superfused for 60-90 min.The time interval between responses was 10-15 min. These experimentswere performed in five rats.

Data Analysis

Values are means ± SE. Multiple comparisons were evaluated by ANOVA and Tukey's test (Systat, Evanston, IL). Differences wereconsidered statistically significant for P < 0.05.

	RESULTS

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Effect of Homocysteine on Resting CBF

First, we studied whether Cu²⁺-homocysteine influences resting CBF. Superfusion with 40 µM Cu²⁺ alone did not affect resting CBF. Superfusion with Cu²⁺ and homocysteine (1 mM) attenuated resting CBF, an effect thatwas maximal after 90 min of superfusion (Fig. 1). At this time,CBF was reduced by 28 ± 4% of baseline (P < 0.05 by ANOVA, n =6). After the superfusion solution was switched back to Ringersolution, CBF was not different from values before Cu²⁺-homocysteine application (Fig. 1; P > 0.05). Cu²⁺-homocysteine superfusion did not produce electrocorticographicevidence of seizures.

Effect of Homocysteine on CBF Responses to ACh, Hypercapnia, SNAP, and Papaverine

In these experiments we sought to determine whether homocysteine affects selected vasodilator responses of the cerebral circulation.During Ringer solution superfusion, 10 µM ACh, hypercapnia (PCO₂= 50-60 mmHg; Table 1), 500 µM SNAP, and 1 mM papaverine increasedCBF (Figs. 2 and 3). The response was not affected by superfusionwith Cu²⁺ (P > 0.05; Figs. 2 and 3). Superfusion with Cu²⁺-homocysteine attenuated the increase in CBF produced by ACh ( $-$ 73± 6%), hypercapnia ( $-$ 31 ± 9%), and SNAP ( $-$ 48 ± 4%; P < 0.05, n= 5), but not that evoked by papaverine (P > 0.05, n = 5; Figs.2 and 3). After the superfusion solution was switched back tonormal Ringer solution, responses to ACh, hypercapnia, SNAP, andpapaverine were not different from those observed before Cu²⁺-homocysteine (P > 0.05; Figs. 2 and 3).

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Fig. 2. Effect of Cu²⁺-homocysteine on increase in CBF produced by topical superfusion of ACh (A) or hypercapnia (B). Cu²⁺-homocysteine, but not Cu²⁺ alone, attenuates increase in CBF produced by ACh or hypercapnia (P < 0.05 by ANOVA and Tukey's test). Effect is reversed by superfusion with Ringer (Ringer 2; P > 0.05 vs. Ringer 1).

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Fig. 3. Effect of Cu²⁺-homocysteine on increase in CBF produced by topical superfusion of NO donor S-nitroso-N-acetylpenicillamine (SNAP, A) or papaverine (B). Cu²⁺-homocysteine, but not Cu²⁺ alone, attenuates increase in CBF produced by ACh (P < 0.05 by ANOVA and Tukey's test). Attenuation is reversed by superfusion with Ringer (Ringer 2; P > 0.05 vs. Ringer 1). Cu²⁺-homocysteine does not affect CBF response to papaverine (P > 0.05).

The relationship between the concentration of homocysteine and its cerebrovascular effects is illustrated in Figs. 4 and 5.The reduction in resting CBF and the attenuation of vasodilatorresponses to ACh, hypercapnia, and SNAP were observed at 1 mMhomocysteine (n = 5, P < 0.05). The response to ACh was slightlyreduced at 500 µM (Fig. 4). However, this reduction did not reachstatistical significance (P > 0.05).

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Fig. 4. Relationship between homocysteine concentration and cerebrovascular effects. Cu²⁺ (40 µM) was included in superfusion solution. Resting CBF (A) and response to ACh (B) are reduced only at 1 mM (P < 0.05 by ANOVA and Tukey's test).

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Fig. 5. Relationship between homocysteine concentration and cerebrovascular effects. Cu²⁺ (40 µM) was included in superfusion solution. CBF responses to hypercapnia (A) and SNAP (B) are reduced only at 1 mM (P < 0.05 by ANOVA and Tukey's test).

Effect of SOD on the Attenuation of Cerebrovascular Dilator Responses

We then investigated whether the cerebrovascular effects of Cu²⁺-homocysteine were mediated by production of superoxide. Topicalsuperfusion of the superoxide scavenger SOD (1,000 U/ml) did notaffect resting CBF or the vasodilation produced by ACh, hypercapnia,or SNAP (Figs. 6 and 7; P > 0.05, n = 5). However, SOD preventedthe reduction of resting CBF and the attenuation of the responseto ACh, hypercapnia, and SNAP produced by Cu²⁺-homocysteine (Figs. 6 and 7; P > 0.05 vs. Ringer).

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Fig. 6. Effect of superoxide dismutase (SOD) on cerebrovascular effects of Cu²⁺-homocysteine. SOD alone does not affect resting CBF (A) or CBF response to ACh (B; P > 0.05 vs. Ringer, by ANOVA and Tukey's test). However, SOD prevents reduction in CBF and attenuation of response to ACh produced by Cu²⁺-homocysteine (P < 0.05 vs. Ringer).

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Fig. 7. Effect of SOD on cerebrovascular effects of Cu²⁺-homocysteine. SOD alone does not affect CBF response to SNAP (A) or hypercapnia (B; P > 0.05 vs. Ringer, by ANOVA and Tukey's test). However, SOD prevents attenuation of CBF response to SNAP and hypercapnia produced by Cu²⁺-homocysteine (P < 0.05 vs. Ringer).

Effect of Homocysteine on Brain NOS Enzymatic Activity

To rule out the possibility that the cerebrovascular effects of homocysteine were related to inhibition of brain NOS, we investigatedthe effects of homocysteine on NOS activity in forebrain homogenates(n = 4). Homocysteine (1-1,000 µM) had no effect on NOS activity,whereas comparable concentrations of N-monomethyl-L-arginine markedlyreduced NOS activity (Fig. 8). These data suggest that homocysteineat a concentration effective in reducing resting CBF and vascularreactivity does not inhibit brain NOS catalytic activity.

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Fig. 8. Effect of homocysteine (HC) on Ca²⁺-dependent NO synthase (NOS) catalytic activity of brain homogenates. HC does not affect NOS activity. In contrast, NOS inhibitor N-monomethyl-L-arginine (L-NMMA) inhibits NOS activity markedly.

	DISCUSSION

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We have demonstrated that homocysteine, in the presence of Cu²⁺, reduces resting CBF and attenuates the increases in CBF producedby ACh, hypercapnia, and SNAP, whereas the response to papaverineis not affected. The cerebrovascular effects of Cu²⁺-homocysteine are prevented by pretreatment with SOD. The datasuggest that homocysteine exerts profound cerebrovascular effectsthat are mediated via Cu²⁺-catalyzed production of superoxide anion.

The cerebrovascular actions of Cu²⁺-homocysteine cannot be attributed to differences in arterial pressure or blood gases, becausethese parameters were closely monitored and controlled and didnot differ between groups. The effect of homocysteine is alsounlikely to result from a nonselective impairment of smooth musclerelaxation, because the increase in CBF produced by papaverinewas not affected. Similarly, the reduced cerebrovascular reactivityto ACh, hypercapnia, or SNAP cannot be attributed to a time-dependentdeterioration of the preparation, because responses returned tonormal after Cu²⁺-homocysteine was discontinued. In addition, in preliminary experiments,we found that superfusion with homocysteine alone for 5 h affectedneither resting CBF nor vasodilator responses to ACh, hypercapnia,or SNAP (F. Zhang and C. Iadecola, unpublished observations).It is also important to point out that the effect of Cu²⁺-homocysteine is not related to endothelial injury, because theincrease in CBF produced by ACh, a response mediated by productionof NO in endothelial cells (25, 35), is fully reestablishedafter discontinuation of homocysteine superfusion. Homocysteinehas been reported to induce seizures (1). However, it is unlikelythat the cerebrovascular effects of homocysteine are due to seizuresor to a postictal state after seizures, because homocysteine superfusiondid not induce electrocorticographic evidence of seizures. Theconcentration of SOD used in the present study (1,000 U/ml) washigher than that used by others (50-100 U/ml) (34). This concentrationwas chosen to ensure that maximal scavenging of superoxide wasachieved. However, SOD at 1,000/U ml did not affect resting CBFor the reactivity to hypercapnia, ACh, and SNAP. Therefore, theeffect of SOD cannot be a consequence of nonspecific actions ofthis enzyme on resting CBF or baseline vasodilator responses.

Homocysteine is emerging as an important risk factor for ischemic stroke (see Ref. 3 for review). Patients with inheriteddeficiency of cystathionine $beta$ -synthase, an enzyme involved inhomocysteine metabolism, have markedly elevated levels of plasmahomocysteine and are more susceptible to ischemic stroke (22).More recently, it has been proposed that homocysteine is a strokerisk factor in patients with moderate elevations of plasma homocysteine(3). Patients with folate deficiency, a condition associatedwith hyperhomocysteinemia, have an increased risk of ischemicstroke (11). Furthermore, case-control studies, including aprospective study (32), have demonstrated that patients withcerebrovascular diseases tend to have increased levels of plasmahomocysteine (2, 4, 7). Therefore, hyperhomocysteinemiamight be a risk factor for ischemic stroke in the general population.

The mechanisms by which increased levels of homocysteine might increase the incidence of cerebral ischemia have not been elucidated.One possibility is that homocysteine predisposes to ischemic injuryby its well-known ability to induce vascular damage, atherosclerosis,and thrombosis (12, 13, 28, 33; see Ref. 24 for review). Anotherpossibility is that homocysteine impairs cerebrovascular regulation,thereby decreasing the ability of the brain circulation to compensatefor the reduction in blood flow that occurs during ischemia. Onepotential mechanism by which homocysteine could compromise vascularregulation is by interfering with the action of endothelial vasodilatorssuch as NO. This possibility is supported by our observation thatthe vasodilation produced by ACh or hypercapnia, responses thatdepend on NO synthesis (10, 14, 35), is attenuated by Cu²⁺-homocysteine, whereas the vasodilation produced by papaverine,a response that is independent of NO (14), is not affected.The attenuation of NO-dependent responses is not related to inhibitionof NOS activity, because homocysteine does not affect Ca²⁺-dependent citrulline production in brain homogenates ex vivo.Rather, the fact that the impairment of NO-dependent responsesis prevented by SOD is consistent with the hypothesis that NOis scavenged by superoxide anion generated by Cu²⁺-homocysteine (23). The observation that, in cranial windowpreparations, generation of superoxide by other means attenuatesNO-dependent cerebrovascular responses supports this conclusion(18, 34). Cu²⁺-homocysteine attenuates also the vasodilation produced by SNAP,a compound that generates NO nonenzymatically, and by hypercapnia,a response that depends on the availability of endogenous NO (16).It would, therefore, seem that superoxide produced by Cu²⁺-homocysteine scavenges NO independently of its source. NO reactswith superoxide extremely rapidly, leading to production of peroxynitrite(8). The mechanisms of superoxide production by autoxidationof thiol are well described and involve reduction of a transitionalmetal followed by reaction of the metal with molecular oxygenand formation of superoxide (6, 21, 23). Thiol autoxidationcan also generate hydrogen peroxide and hydroxyl radicals (28).The role of these reactive oxygen species in our model has notbeen established and needs to be investigated in future studies.

Homocysteine has also been reported to react directly with NO to form S-nitrosohomocysteine, a product that retains the vasoactiveproperties of NO but is less cytotoxic than homocysteine (27).Although S-nitrosohomocysteine could be formed in our model, itis unlikely that this process is the predominant mechanism responsiblefor the attenuation of NO-dependent responses. This is becausethe reaction of NO with superoxide is faster than S-nitrosation(8). Moreover, S-nitrosylated species do not block vasodilation;rather, they retain the vasodilatory effect of NO (27). Homocysteinecan also react with adenosine to form S-adenosylhomocysteine,a reaction catalyzed by a specific hydrolase present in the centralnervous system (5). This reaction can, therefore, lower theextracellular concentration of adenosine, a potent cerebrovasodilator,and decrease resting CBF (26). However, it is unlikely thatthe findings of the present study are related to this mechanism.Adenosine is not involved in the increase in CBF produced by AChor NO donors (9, 20) and, consequently, lack of adenosinecould not explain the reduction in these responses induced byhomocysteine. Furthermore, the reaction of adenosine with homocysteineshould not be superoxide dependent and, as such, the effect ofhomocysteine should not be prevented by SOD.

The cerebrovascular effects of homocysteine were observed at 1 mM, a concentration similar to that used in previous studiesin which other vascular effects of exogenous homocysteine wereinvestigated (26-29). These concentrations are higher than thoseobserved in patients with inherited or acquired hyperhomocysteinemia(31). Therefore, findings obtained with high concentrationsof homocysteine should be interpreted with caution. However, reductionin endothelium-dependent vasodilation has been reported in thecarotid artery of monkeys in which the plasma concentrations ofhomocysteine were increased only to ~11 µM by dietary measures(19). This finding may suggest that chronic exposure to moderatelyelevated levels of homocysteine may be more effective than acuteexposure. In addition, because there is compartmentation of homocysteinein tissues (30), it is conceivable that intracellular and interstitialconcentrations are higher than plasma concentrations. Alternatively,other factors may play a role in the reduction of the vascularresponses in diet-induced hyperhomocysteinemia (see Ref. 19for discussion). These hypotheses remain to be tested experimentally.Studies in chronic models of hyperhomocysteinemia with moderateelevation of plasma homocysteine would be needed to address thisissue.

The present results provide an additional insight into the mechanisms of the increased susceptibility of cerebral ischemiaobserved in hyperhomocysteinemia. There is substantial evidencethat the vascular-hemodynamic effects of NO are beneficial inthe early stages of cerebral ischemia (15). Immediately afterischemia, NO may facilitate collateral flow to the ischemic territoryand maintain microvascular patency by inhibiting platelet aggregation(15). In hyperhomocysteinemia, NO scavenging by superoxide maylimit the amount of NO available to exert these beneficial hemodynamiceffects, resulting in worsening of cerebral perfusion. Increasedplatelet aggregation resulting from removal of NO may promotethombus extension and microvascular occlusions. Additional studies,however, are required to determine whether hyperhomocysteinemiaworsens the outcome of experimental cerebral ischemia and, ifso, whether the effect is related to a greater flow reductionin the ischemic territory and to increased platelet aggregation.

In conclusion, we have demonstrated that 1 mM homocysteine, in the presence of Cu²⁺, reduces resting CBF and selectively attenuates the increasein CBF produced by ACh, hypercapnia, and SNAP, responses entirely,or in part, mediated by NO. The cerebrovascular effects of homocysteineare prevented by the superoxide scavenger SOD. The data are consistentwith the hypothesis that superoxide, generated from metal-catalyzedoxidation of homocysteine's thiol group, scavenges NO and decreasesthe availability of NO for vasodilation. Because the cerebrovascularand antiplatelet effects of NO are beneficial in the early stagesof cerebral ischemia, homocysteine-induced scavenging of NO maybe one of the mechanisms by which this amino acid worsens theoutcome of cerebral ischemia. However, future studies using moreclinically relevant models of hyperhomocysteinemia are requiredto better assess the impact of these cerebrovascular effects onthe cerebrovascular complication of this condition.

	ACKNOWLEDGEMENTS

The editorial assistance of Karen MacEwan is gratefully acknowledged.

	FOOTNOTES

This study was supported by National Institute of Neurological Disorders and Stroke Grant NS-34179 to C. Iadecola. C. Iadecolais an Established Investigator of the American Heart Association.

Address for reprint requests: C. Iadecola, Dept. of Neurology, University of Minnesota Medical School, Box 295 UMHC, 420 Delaware St. SE, Minneapolis, MN 55455.

Received 18 November 1997; accepted in final form 5 February 1998.

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