Tonic regulation of vascular tone by nitric oxide and chloride ions in rat isolated small coronary arteries

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Tonic regulation of vascular tone by nitric oxide and chloride ions in rat isolated small coronary arteries

Jonathan E. Graves, Iain A. Greenwood, and William A. Large

Department of Pharmacology and Clinical Pharmacology, St. George's Hospital Medical School, London SW17 ORE, United Kingdom

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

We have investigated the involvement of Cl in regulating vascular tone in rat isolated coronary arteries mounted on a smallvessel myograph. Mechanical removal of the endothelium or inhibitionof nitric oxide (NO) synthase with N-nitro-L-arginine methyl ester (L-NAME, 10⁴ M) led to contraction of rat coronary arteries, and these contractionswere sensitive to nicardipine (10⁶ M). This suggests that release of NO tonically inhibits a contractilemechanism that involves voltage-dependent Ca²⁺ channels. In arteries contracted with L-NAME, switching the bathingsolution to physiological saline solution with a reduced Cl concentration potentiated the contraction. DIDS (5 × 10⁶-3 × 10⁴ M) caused relaxation of L-NAME-induced tension (IC₅₀ = 55 ± 10µM), providing evidence for a role of Cl. SITS (10⁵-5 × 10⁴ M) did not affect L-NAME-induced tension, suggesting that DIDSis not acting by inhibition of anion exchange. Mechanical removalof the endothelium led to contraction of arteries, which was sensitiveto DIDS (IC₅₀ = 50 ± 8 µM) and was not affected by SITS. Thisstudy suggests that, in rat coronary arteries, NO tonically suppressesa contractile mechanism that involves a Clconductance.

chloride channel; vascular smooth muscle

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

THE ENDOTHELIUM plays an important role in regulating vascular tone in many vascular beds, including the coronary circulation.In pressurized rat isolated small coronary arteries, nitric oxide(NO) modulates myogenic tone induced by increases in intravascularpressure (10). In the human coronary vascular bed, endothelium-derivedNO contributes to metabolic vasodilation of large epicardial arteries(6), and mechanical removal of the endothelium increases intrinsictone in the rat isolated coronary artery (23). This is of particularinterest, inasmuch as removal of the endothelium or inhibitionof NO synthase in arteries mounted as ring preparations from manyother vascular beds produces little or no increase in basal tension(12, 16, 22, 28), although the effects of contractileagonists are potentiated (12, 16). This suggests that themechanism producing contraction of coronary arteries in responseto removal of the endothelium may not be present in the systemiccirculation and is therefore a potential therapeutic target fora selective coronaryvasodilator.

The potential importance of this observation is underlined by the well-documented finding that endothelial dysfunction isa feature of cardiovascular disease, including hypertension (7),diabetes (26), and atherosclerosis (19), all of which arerisk factors for coronary artery disease. The association of endothelialdysfunction with increased risk of coronary artery disease suggeststhat coronary vasoconstriction due to reduction in tonic endothelium-derivedNO may contribute to impaired myocardialperfusion.

Recent studies have suggested that the endothelium may regulate vascular tone via an effect on vascular smooth muscle Cl channels (16). In these studies, norepinephrine-induced contractionsof rat aorta were potentiated by reducing the Cl concentration of the bathing solution, which suggests that outwardmovement of Cl plays an important role in the contraction. This effect was potentiatedin arteries treated with an NO synthase inhibitor or with theendothelium removed. In addition, low-Cl solution also initiated contraction in unstimulated arterieswithout endothelium but did not cause contraction in arterieswith an intact endothelium. These results are consistent witha role for membrane Cl conductances as depolarizing mechanisms in vascular smooth muscle(18). Moreover, the above data suggest that an intrinsic Cl mechanism is suppressed byNO.

We have therefore investigated how the coronary endothelium regulates intrinsic vascular tone in rat isolated small coronaryarteries and explored the role of Cl in mediating the contraction caused by removal of endothelium-derivedNO.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Male Wistar rats (250-350 g) were killed by cervical dislocation, and the heart was removed immediately and placed in coldbuffer. Typically, two 1.5- to 2.0-mm sections of the septal arterywere dissected from the interior wall of the right ventricle andmounted as ring preparations on a small vessel myograph within1 h (n = 76, 285 ± 5 µm ID at 100 mmHg). The arteries were maintainedat 37°C bubbled with 95% O₂-5% CO₂ in physiological saline solution(PSS) of the following composition (mM): 119 NaCl, 4.7 KCl, 2.5CaCl₂, 1.17 MgSO₄, 25 NaHCO₃, 1.18 NaH₂PO₄, 0.026 EDTA, and 6.0glucose. Arteries were allowed to equilibrate for 1 h before estimationof the internal circumference that they would have at a passivetransmural pressure of 100 mmHg in vivo (22). A series of stretches(4-6) were performed such that the calculated (from the Laplaceequation) effective pressure exceeded 100 mmHg on the final stretch.From this, the arteries were set to a normalized diameter of 90%of that which they would have assumed in vivo. After a further30-min equilibration, a series of three contractions to K-PSS(equimolar substitution of NaCl with KCl) was carried out, withthe arteries being exposed to K-PSS for 2 min every 10min.

Protocols

Effect of NO synthase inhibition and the role of Na+ and Cl. To examine the influence of NO on vascular tone, 10⁴ M N-nitro-L-arginine methyl ester (L-NAME) was added to the myograph bath,and the tension was recorded for up to 3 h. The contribution ofCl and Na⁺ to the contraction elicited by L-NAME was investigated by theuse of low-Cl and low-Na⁺ PSS solutions. After contraction to L-NAME, the solution in themyograph bath was washed to either PSS or to low-Cl PSS (equimolar substitution of NaCl with sodium isothionate)or low-Na⁺ PSS (equimolar substitution of NaCl with choline chloride + 10⁶ M atropine or equimolar substitution of NaCl with N-methyl-D-glucaminechloride), and the change in tension was recorded for 5 min inthe continued presence of L-NAME before the solution was washedto PSS and L-NAME (10⁴M).

Effect of Cl channel blockers on voltage-dependent Ca²+ channels. To examine the effect of Cl channel blockers on voltage-dependent Ca²⁺ channels (VDCCs), cumulative concentration-response curves toCl channel blockers were carried out on coronary arteries precontractedwith 45 mM K⁺. After a stable contraction to K⁺ was established, Cl channel blockers were added in increasing concentrations every4 min. Drugs that did not affect the K⁺ spasm at concentrations at which they had previously been shownto affect Cl channels in electrophysiological studies were then tested onthe contraction to L-NAME.

Effect of Cl channel blockers on L-NAME-induced tension. To investigate the role of Cl channels on the contraction to L-NAME, cumulative concentration-response curves to Cl channel blockers were carried out in arteries contracted withL-NAME. Increasing concentrations of DIDS and SITS were addedevery 4 min. Inasmuch as the level of precontraction can affectthe response to vasodilators, only arteries that contracted >0.5mN/mm were used to examine the effects of the stilbenederivatives.

Effect of endothelial removal on vascular tone and the effect of Cl channel blockers. Two sections of the same septal artery were mounted and contracted with U-46619 (10⁷ M) and challenged with ACh (10⁷-10⁵ M). After washout, the endothelium was removed from one arteryby careful rubbing with a human forearm hair while the arterywas still mounted on the myograph; the other artery was used asa control. The arteries were then contracted with U-46619 (10⁷ M) and challenged with ACh, and a <10% relaxation to ACh wastaken as evidence of endothelial removal. After washout, the arterieswere left until they had contracted >0.5 mN/mm. Subsequently,a cumulative concentration response to DIDS (5 × 10⁶-3 × 10⁴ M) was carried out, with increasing concentrations of DIDS beingadded every 4min.

Effect of Cl transport inhibitors on L-NAME-induced tension. The effect of the K⁺-Na⁺-2Cl cotransporter inhibitor bumetanide (10⁵ M) was investigated on arteries precontracted with L-NAME. Aftercontraction to L-NAME, arteries were exposed for 30 min to bumetanide,and tension was recorded. SITS (5 × 10⁴ M) was then added in the continued presence of bumetanide, andtension was recorded after a further 30min.

Drugs

DIDS, SITS, tamoxifen, 9,11-dideoxy-11 $alpha$ ,9 $alpha$ -epoxymethanoprostaglandin F₂ (U-46619), ACh hydrochloride, niflumic acid,5-nitro-2-(3-phenylpropylamino)benzoic acid, L-NAME, and nicardipinewere obtained from Sigma Chemical (Poole, UK). IAA-94 was obtainedfrom Research Biochemicals (Natick,MA).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Effect of Inhibition of NO Synthase on Tension of Rat Septal Arteries

Incubation with the NO synthase inhibitor L-NAME caused contraction of >0.50 mN/mm in 70% of arteries and some contractionin all arteries. A representative trace of the effect of L-NAMEis shown in Fig. 1A, and the contraction to L-NAME was well maintainedfor up to 3 h. In 44 arteries, L-NAME induced a contraction of1.10 ± 0.12 mN/mm. The contraction to L-NAME was unaffected by0.1-0.5% DMSO, which was used as a vehicle for drugs, but wasgreatly attenuated (95 ± 3%, n = 5) by the voltage-gated Ca²⁺ channel blocker nicardipine (10⁶ M). In three arteries, removal of the endothelium caused contractionof 0.76 ± 0.11 mN/mm, and this contraction was abolished by nicardipine(10⁶ M). A representative trace of the effect of nicardipine is shownin Fig. 1B. These data suggest that inhibition of NO synthaseand removal of the endothelium initiate contraction by a mechanismthat involves Ca²⁺ entry through VDCCs.

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Fig. 1. Effect of N-nitro-L-arginine methyl ester (L-NAME) and endothelial denudation on tension of rat isolated coronary arteries mounted on a small vessel myograph. A: representative trace showing contraction to L-NAME and the effect of addition of 0.1% DMSO and 10⁶ M nicardipine. B: representative trace showing contraction to endothelial denudation and the effect of 10⁶ M nicardipine.

Effect of Low-Cl Solution on Basal and L-NAME-Induced Tone

VDCCs are opened by membrane depolarization, and therefore it is possible that NO suppresses a depolarizing mechanism. Insmooth muscle the ionic mechanisms most likely to give rise toa depolarization are efflux of Cl and influx of Na⁺. Replacing the Cl with a less-permeant anion (isethionate) will increase the outwardelectrochemical gradient for Cl and thus potentiate contraction if it is dependent on the outwardmovement of Cl. In six arteries, washout to low-Cl PSS had only a small effect on tension on unstimulated arteriescompared with washout to normal PSS (Fig. 2A). In contrast, inthe same six arteries, when contraction had been induced by L-NAME(contraction = 0.99 ± 0.17 mN/mm), substitution of PSS by low-Cl PSS led to a potentiation of the contraction (Fig. 2B). Thesedata are consistent with the proposal that the contraction inducedby L-NAME involves the outward movement of Cl.

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Fig. 2. Effect of low-Cl solution on tension in rat isolated small coronary arteries mounted on a small vessel myograph before and after contraction with L-NAME. Change in tension was measured every 1 min for 5 min after bathing solution was switched. A: effect of replacement of physiological saline solution (PSS) with low-Cl PSS on basal tension of rat isolated coronary arteries before addition of L-NAME. B: effect of replacement of PSS with low-Cl PSS on tension of rat isolated coronary arteries after contraction to L-NAME. Each point is mean ± SE of 6 arteries.

Effect of Low-Na+ Solutions on L-NAME-Induced Tone

Depolarization of vascular smooth muscle can also occur by the opening of nonspecific cation channels and subsequent Na⁺ influx (3). Replacement of the Na⁺ by a relatively impermeant cation in the bathing solution shouldcause relaxation of the vascular smooth muscle if this mechanismis involved in the contraction to L-NAME. In four arteries treatedwith L-NAME (contraction = 1.25 ± 0.30 mN/mm), replacement ofPSS by low-Na⁺ PSS (N-methyl-D-glucamine chloride substitution) gave an initialrelaxation that was not significantly different from wash to normalPSS (Fig. 3), and this was followed by a substantial contraction.In four separate arteries treated with L-NAME (contraction = 0.88± 0.20 mN/mm), wash to low-Na⁺ PSS (choline chloride substitution) also led to an immediateand profound contraction (Fig. 3). We are uncertain as to themechanism of the contraction in low-Na⁺ PSS, but these data clearly suggest that influx of Na⁺ is not responsible for the contraction to L-NAME.

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Fig. 3. Effect of reducing extracellular Na⁺ concentration on tension of rat isolated small coronary arteries mounted on a small vessel myograph and contracted with L-NAME. Change in tension is shown from point 0.0, measured every 1 min for 5 min, for effect of replacement of PSS with low-Na⁺ PSS with N-methyl-D-glucamine (NMDG) substitution or low-Na⁺ PSS with choline chloride substitution + 10⁶ M atropine. Values are means ± SE of 4 arteries for each plot.

Effect of Cl Current Inhibitors on K+-Induced Tone

In the next series of experiments, we investigated the effects of agents that have been shown to inhibit various Cl conductances in electrophysiological experiments. Drugs thathave been shown to inhibit Cl channels in electrophysiological experiments can have other effectsthat would also lead to vasodilation in functional studies, namely,inhibition of VDCCs and opening of K⁺ channels (5, 13). To investigate the effects of Cl channel blockers on VDCCs, we examined their effects on the nicardipine-sensitivecontraction induced by 45 mM K-PSS in arteries with an intactendothelium. The stilbene derivatives DIDS and SITS did not causerelaxation of tension induced by 45 mM K-PSS and, therefore, didnot block VDCCs in this preparation. Tension remaining after exposureof arteries precontracted with 45 mM K⁺ to DIDS (3 × 10⁴ M) was 101 ± 7% (n = 4). A representative trace of the effectsof DIDS is shown in Fig. 4A. In contrast, all the other Cl channel blockers tested caused relaxation of 45 mM K-PSS-inducedtension and included tamoxifen (10⁵ M, 78 ± 10%, n = 3), 5-nitro-2-(3-phenylpropylamino)benzoic acid(3 × 10⁶ M, 61 ± 12%, n = 4), IAA-94 (10⁴ M, 58 ± 11%, n = 4), and niflumic acid (2 × 10⁴ M, 40 ± 9%, n = 4). Therefore, we tested the stilbene derivativesDIDS and SITS against the contraction produced by L-NAME or endothelialremoval.

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Fig. 4. Effect of DIDS and levcromakalim on K⁺-induced tension in rat isolated small coronary arteries mounted on a small vessel myograph. A: representative trace showing the lack of effect of 75-300 µM DIDS on tension induced by 45 mM K⁺. B: representative trace showing relaxation to 1-10 µM levcromakalim (Lev) on tension induced by 45 mM K⁺.

The K⁺ channel opener levcromakalim (10⁶-10⁵ M) induced relaxation in rat isolated coronary arteries contracted with 45 mM K-PSS,and the maximum relaxation to 10⁵ M was 73 ± 3% (n = 5); a representative trace is shown in Fig.4B. Levcromakalim did not cause relaxation of tension in arteriescontracted with 60 mM K-PSS. These data suggest that levcromakalimis causing relaxation of arteries contracted by 45 mM K-PSS byopening K⁺ channels, and therefore the observation that DIDS did not causerelaxation of 45 mM K-PSS-induced tension indicates that the agentis not acting as a K⁺ channelopener.

Effect of Stilbene Cl Channel Blockers on L-NAME-Induced Tone

Addition of DIDS (5 × 10⁶-3 × 10⁴ M) caused concentration-dependent relaxation of coronary arteries contracted by addition ofL-NAME (contraction = 1.25 ± 0.28 mN/mm, n = 8); a representativetrace and a summary of the data are shown in Fig. 5. The IC₅₀for DIDS against L-NAME was 55 ± 10 µM (n = 8). In coronary arteriesprecontracted with U-46619 (contraction = 1.40 ± 0.14 mN/mm, n= 5), DIDS elicited a relaxation but was markedly less potentthan against the L-NAME-induced contraction (Fig. 5B), and 150µM DIDS produced 50% relaxation of the contraction to U-46619.In a separate series of six arteries, L-NAME caused a contractionof 0.89 ± 0.12 mN/mm, and addition of the stilbene derivativeSITS (10⁵-5 × 10⁴ M) did not cause relaxation. The percentage of the initial tensionremaining after 5 × 10⁴ M SITS was 107 ± 14%.

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Fig. 5. Effect of DIDS on tension of rat isolated small coronary arteries. A: representative trace demonstrating the effect of DIDS on the tension increase caused by 10⁴ M L-NAME. B: effect of 5 × 10⁶-3 × 10⁴ M DIDS on tension of arteries contracted with 10⁴ M L-NAME (n = 8) and arteries contracted with 3 × 10⁸-10⁷ M U-46619 (n = 5). Summary data are means ± SE.

Effect of Mechanical Removal of the Endothelium

The maximum relaxation to ACh was 63 ± 5% when the artery was precontracted with U-46619 before mechanical removal of theendothelium, and after the endothelium was removed, the maximumrelaxation was reduced to 1 ± 3%. A representative trace showingthe contractile effect of endothelial removal and the subsequentrelaxation to DIDS (5-300 µM) is shown in Fig. 6A. In this experiment,after washout of DIDS, the artery contracted again, and a singledose of SITS (500 µM) was added that produced only a small relaxation.Inasmuch as SITS would be expected to cause a substantial blockadeof the anion exchanger, the above evidence suggests that the DIDS-inducedrelaxation is not due to inhibition of this mechanism. All fivearteries subjected to mechanical removal of the endothelium contracted(mean contraction = 0.64 ± 0.05 mN/mm after 52 ± 5 min; mean contractionin 5 control arteries with intact endothelium = 0.01 ± 0.04 mN/mm).A concentration response to DIDS was carried out, and the meanresults are shown in Fig. 6B. DIDS caused a concentration-dependentrelaxation in endothelium-denuded arteries, with a maximum relaxationof $-$ 0.80 ± 0.11 mN/mm, slightly below the original baseline. TheIC₅₀ for DIDS was 50 ± 8 µM (n = 5). The presence of some intrinsictone that was sensitive to DIDS in these experiments was confirmedby the slight relaxation of arteries with an intact endotheliumof 0.10 ± 0.05 mN/mm.

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Fig. 6. Effect of DIDS on contraction of rat isolated small coronary arteries induced by endothelial removal. A: representative trace showing the effect of increasing concentrations of DIDS (5 × 10⁶-3 × 10⁴ M) on tension induced by mechanical removal of the endothelium of a rat isolated coronary artery. After washout of DIDS, a single concentration of SITS (500 µM) was added. B: effect of DIDS on tension in rat isolated coronary arteries with (n = 5) or without (n = 5) endothelium. Summary data are means ± SE.

Effect of Cl Transport Inhibitors on L-NAME-Induced Tension

We investigated the effect of inhibitors of the Na⁺-K⁺-2Cl cotransporter (bumetanide) and Cl/HCO₃ exchanger (SITS) that would be expected to reduce the outwardCl gradient. L-NAME contracted four arteries (0.54 ± 0.05, n = 4),and addition of bumetanide (10 µM) caused a small contractionthat was 16 ± 8% of the initial tension after 5 min (Fig. 7).This was followed by a relaxation of 25 ± 4% of the initial tensionafter 30 min. Addition of SITS (500 µM) caused a further relaxationof 78 ± 4% of the initial tension.

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Fig. 7. Effect of Cl transport inhibitors on contraction of rat isolated small coronary arteries induced by 10⁴ M L-NAME. A: representative trace showing effect of addition of 10⁵ M bumetanide and subsequent addition of 5 × 10⁴ M SITS. B: summary effect of bumetanide and bumetanide + SITS on tension increases induced in rat small coronary arteries by L-NAME (n = 4). *P < 0.05 vs. L-NAME; **P < 0.001 vs. L-NAME (by ANOVA). Values are means ± SE.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The major finding of this study is that, in rat isolated small coronary arteries, endothelium-derived NO provides a tonicinhibition of an intrinsic contractile mechanism that involvesCl. The contractile effects of L-NAME and removal of the endotheliumconfirm the contribution of NO from the endothelium as a tonicvasodilator influence. The contraction is mediated by entry ofCa²⁺ into the vascular smooth muscle via VDCCs, inasmuch as the contractionsare sensitive to nicardipine. This suggests that, in arterieswith a functioning endothelium, NO suppresses an intrinsic depolarizingmechanism and subsequent removal of NO produces depolarizationof the smooth muscle cells to open VDCCs to cause contraction.Future studies simultaneously measuring tension by means of themyograph and membrane potential by microelectrode will be carriedout to confirm the central role of a depolarizingmechanism.

There are three potential depolarizing influences involving ion channels in vascular smooth muscle: opening of Cl channels leading to Cl efflux, opening of nonspecific cation channels leading to Na⁺ influx, and closing of K⁺ channels. The potentiation of the contraction to L-NAME by reductionof extracellular Cl is consistent with an outward movement of Cl through a Cl channel being responsible for the depolarization. If a nonspecificcation channel were mediating the depolarization, reduction ofextracellular Na⁺ would be expected to decrease depolarization and contraction,whereas this procedure produced a contraction. This suggests thatthe contraction induced by L-NAME is not mediated by a nonspecificcation channel. However, a degree of caution is necessary in interpretingthe data from ion substitution experiments, since we do not haveprecise information on the intracellular ion concentrations. Inaddition, other ion transport mechanisms may be affected. Thereis evidence for NO opening K⁺ channels to cause hyperpolarization (1, 2), and we cannotrule out the possibility that removal of a hyperpolarizing K⁺ influx could play a role in the contraction to L-NAME. Nevertheless,the data imply that when NO is removed, the smooth muscle cellsof the rat coronary circulation depolarize sufficiently to openVDCCs to produce contraction. This is clearly different from mostsystemic arteries, where inhibition of NO synthesis or mechanicalremoval of the endothelium does not evoke contraction. A recentreport demonstrated that the endothelium inhibits anion channel-dependentcontractions of rat aortic rings elicited by substitution of themore-permeable anion I for Cl (17). In contrast to our study, removal of the endotheliumalone in the rat aorta did not lead to significant contraction,and the endothelial factor involved was notNO.

Relaxation by DIDS of arteries contracted by L-NAME or removal of the endothelium is further evidence for a role of Cl in mediating the contraction. The relaxation to DIDS is observedin endothelium-denuded vessels and is therefore due to a directeffect on the vascular smooth muscle. We have demonstrated thatDIDS is not acting as a VDCC blocker. We also attempted to examinewhether DIDS relaxed the artery by opening of K⁺ channels. DIDS did not relax the contraction to 45 mM K⁺, which was inhibited by the K⁺ channel opener levcromakalim. Levcromakalim did not inhibit thecontraction produced by 60 mM K⁺. However, without membrane potential measurement, this conclusionis tentative, inasmuch as K⁺ equilibrium potential, and presumably membrane potential, shouldbe around $-$ 30 mV, and levcromakalim may not be able to hyperpolarizethe smooth muscle under theseconditions.

The most likely explanation for the vasodilator action of DIDS is via its effects on mechanisms involving Cl. In addition to blockade of Cl channels, the stilbene derivatives also block the Cl/HCO₃ exchanger mechanism, which may be involved in maintaining intracellularCl concentration. Blockade of this mechanism could induce relaxationby reducing the Cl electrochemical gradient that is responsible for the depolarizinginfluence of opening Cl channels. However, SITS, which has a potency similar to DIDSon the Cl/HCO₃ exchanger (4, 9), did not relax coronary arteries whenadded on its own. However, bumetanide, an inhibitor of the Na⁺-K⁺-2Cl cotransporter, produced a relaxation of the L-NAME-induced contractionafter 30 min. Subsequent addition of SITS in the continued presenceof bumetanide produced a substantial relaxation. This result suggeststhat both Cl transport mechanisms are able to maintain an outward Cl electrochemical gradient in these arteries and that the contractionto L-NAME is dependent on this electrochemical gradient beingmaintained. The vasodilator action of DIDS is not likely to bedue to inhibition of inward Cl transportsystems.

Other potential targets for DIDS are membrane Cl conductances, which produce depolarization in vascular smooth muscle. TwoCl currents have been identified in vascular smooth muscle: theCa²⁺-activated Cl current [I_Cl(Ca)] and the swell-activated Cl current [I_Cl(swell)]_. The IC₅₀ for DIDS against I_Cl(Ca) is 200-700µM (18), similar to the concentration (150 µM) required to cause50% relaxation of coronary arteries contracted with U-46619 .Therefore, it is possible that U-46619 activates I_Cl(Ca) to producecontraction in this tissue. Previously, it was suggested thatI_Cl(Ca) represents a depolarizing mechanism for agonist-inducedcontraction in blood vessels (18). DIDS is an effective inhibitorof I_Cl(swell), with an IC₅₀ of 21 µM in rabbit isolated portalvein smooth muscle cells (14), which is similar to the IC₅₀of 55 µM estimated for DIDS against L-NAME-induced contraction,and an IC₅₀ of 50 µM for DIDS against the contraction to endothelialremoval in the present study. In contrast, SITS has been shownto be much less potent than DIDS against I_Cl(swell) in caninecolonic myocytes (5). It is worth noting that the inhibitoryeffect of DIDS against the contraction to L-NAME was much morerapid than the relaxation induced by bumetanide + SITS. Theseresults are consistent with DIDS acting as a channel blocker (14)and bumetanide and SITS as transport inhibitors. Preliminary studiesshow that NO inhibits I_Cl(swell) in rabbit isolated portal veinsmooth muscle cells (8). Consequently, it is possible thatI_Cl(swell) may represent the depolarizing mechanism that is suppressedby NO in rat isolated coronary arteries. However, the preciseidentification of which Cl channels may be involved will require single-cell electrophysiologicalstudies.

The mechanism underlying the contraction to low Na⁺ (25 mM) is interesting and appears to involve depolarization of the vascularsmooth muscle, inasmuch as the contraction was sensitive to nicardipine(J. Graves, unpublished observations). Na⁺-K⁺-ATPase has been reported to be inhibited by low extracellularNa⁺ (<50 mM), and inhibition of this electrogenic mechanism wouldcause depolarization and thus contraction. The contraction tolow Na⁺ is of interest, inasmuch as it presents another feature of thesecoronary arteries that is very different from that previouslyreported for systemic arteries. It has been reported that ratisolated mesenteric resistance arteries do not contract to low-Na⁺ solutions unless they are pretreated with ouabain (20). Inaddition, low-Na⁺ solutions potentiate myogenic tone in arteries and veins, althoughthe low-Na⁺ solutions used in this study may have had reduced Cl content (15).

Interestingly, human epicardial arteries also contract when treated with NO synthase inhibitors (27), and this raises thepossibility that a similar mechanism exists in the human coronarycirculation. Spontaneous contractile activity of human isolatedcoronary arteries that is sensitive to Ca²⁺ channel antagonists has also been described (25). This intrinsicactivity and contraction to disruption of the NO pathway is notseen in most small systemic arteries. Thus this Cl mechanism, if present in humans, may provide a potential therapeutictarget for selective vasodilation of coronary arteries. Sincethis contractile mechanism may be prominent in arteries with adamaged endothelium, agents targeting this mechanism may act morepotently on diseased arteries and thus avoid cardiacsteal.

Conclusion

We have provided evidence that a mechanism involving Cl, possibly a Cl conductance, is involved in the contraction of rat coronary arteriesproduced by removal of endothelium-derived NO. This mechanismmay be of great importance in cardiovascular disease associatedwith disturbances in the coronary circulation and is a novel targetfortherapy.

	ACKNOWLEDGEMENTS

This work was supported by the British Heart Foundation and The WellcomeTrust.

	FOOTNOTES

Address for reprint requests and other correspondence: J. E. Graves, Dept. of Pharmacology and Clinical Pharmacology, St.George's Hospital Medical School, London SW17 ORE, UK (E-mail:jgraves{at}sghms.ac.uk).

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.

Received 9 May 2000; accepted in final form 4 August 2000.

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