Abstract
We investigated the effects of the Cl− channel blockers niflumic acid, 5-nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB) and 4,4′-diisothiocyanatostilbene-2,2′-disulphonic acid (DIDS) on endothelin-1 (ET-1)-induced constriction of rat small pulmonary arteries (diameter 100–400 μm) in vitro, following endothelium removal. ET-1 (30 nM) induced a sustained constriction of rat pulmonary arteries in physiological salt solution. Arteries preconstricted with ET-1 were relaxed by niflumic acid (IC50: 35.8 μM) and NPPB (IC50: 21.1 μM) in a reversible and concentration-dependent manner. However, at concentrations known to block Ca++-activated Cl− channels, DIDS (≤500 μM) had no effect on the ET-1-induced constriction. Similar results were obtained when pulmonary arteries were preincubated with these Cl− channel blockers. When l-type Ca++ channels were blocked by nifedipine (10 μM), the ET-1-induced (30 nM) constriction was inhibited by only 5.8%. However, niflumic acid (30 μM) and NPPB (30 μM) inhibited the ET-1-induced constriction by ∼53% and ∼60%, respectively, both in the continued presence of nifedipine and in Ca++-free physiological salt solution. The Ca++ ionophore A23187 (10 μM) also evoked a sustained constriction of pulmonary arteries. Surprisingly, the A23187-induced constriction was also inhibited in a reversible and concentration-dependent manner by niflumic acid (IC50: 18.0 μM) and NPPB (IC50: 8.8 μM), but not by DIDS (≤500 μM). Our data suggest that the primary mechanism by which niflumic acid and NPPB inhibit pulmonary artery constriction is independent of Cl− channel blockade. One possibility is that these compounds may block the Ca++-dependent contractile processes.
Although Ca++-activated Cl−channels have been observed in smooth muscle cells in a variety of tissues (see review Large and Wang, 1996), the functional role of Cl− channels in vascular smooth muscle is still unclear. However, because the equilibrium potential of Cl− in smooth muscle is regarded to be between −20 and −30 mV (Aickin, 1990), it is generally assumed that activation of Cl− channels could lead to membrane depolarization and activation of voltage-gated Ca++ channels (VGCCs), resulting in Ca++ entry and contraction (Large and Wang, 1996). This is supported by the observation that the Cl− channel blocker niflumic acid depresses noradrenaline-evoked contraction of rat aorta (Criddle et al., 1996) and by the fact that niflumic acid and DIDS (4,4′-diisothiocyanatostilbene-2,2′-disulphonic acid) have been shown to inhibit noradrenaline or phenylephrine-induced constriction of rat pulmonary arteries (Wang et al., 1997; Yuan, 1997). In addition, Nelson et al. (1997) showed that the Cl− channel blockers indanyloxyacetic acid (IAA-94) and DIDS cause hyperpolarization and dilation in pressurized rat cerebral arteries, although they suggested that niflumic acid-sensitive Cl− channels were unlikely to be involved in this mechanism.
It is well known that endothelin-1 (ET-1) is one of the most potent constrictors of vascular smooth muscle and that it mediates its effects via at least two receptor subtypes, ETA and ETB (Yanagisawa et al., 1988; Arai et al., 1990;Leach et al., 1990; Sakurai et al., 1990; Sakamoto et al., 1991;Yoshida et al., 1994; Maguire et al., 1996). In a previous study using the patch-clamp technique, Salter and Kozlowski (1996) showed that ET-1 has three electrophysiological effects on rat pulmonary arterial smooth muscle cells: 1) activation of a Ca++-activated Cl− current (ICl(Ca)); 2) enhancement of a Ca++-activated K+ current, both of which are mediated by ETA receptors; and 3) inhibition of the delayed rectifier K+ current (IKV), which is mediated by ETB receptors. Of these three effects, activation of ICl(Ca) and inhibition ofIKV have the capacity to induce membrane depolarization in rat small pulmonary arteries. More specifically, ET-1 may induce constriction of pulmonary arterial myocytes, at least in part, by activatingICl(Ca), which may in turn produce membrane depolarization and Ca++ influx through VGCCs. Several studies have shown that niflumic acid, 5-nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB), and DIDS block activation of ICl(Ca) in isolated pulmonary artery smooth muscle cells (e.g., Clapp et al., 1996; Salter and Kozlowski, 1996). However, the relationship between the observed activation of ICl(Ca) and the constriction induced by ET-1 has yet to be studied in intact pulmonary arteries.
The purpose of this study was to examine the role ofICl(Ca) activation in ET-1-induced constriction of rat small pulmonary arteries. All experiments were conducted using endothelium-denuded arteries to obviate the involvement of the endothelium. Our data suggest that activation ofICl(Ca) is unlikely to play an essential role in ET-1-induced constriction of pulmonary arteries. In addition, our data demonstrate that niflumic acid and NPPB may relax these arteries by mechanism(s) independent of Cl− channel inhibition.
Materials and Methods
Tissue Isolation and Tension Measurement.
Male Wistar rats (250–350 g) were sacrificed with an overdose of pentobarbitone (40 mg/kg b.wt., i.p.). The heart and lungs were removed and then the small pulmonary arteries (i.d. 100–400 μm; length 1–2 mm) were dissected free of the surrounding connective tissue and adventitia. After the dissection, two arteries were immediately mounted on a Mulvany and Halpern-type Myograph (Mulvany and Halpern, 1977; JP Trading, Aarhus, Denmark). Additional arteries were stored in a refrigerator at 4°C until needed. The arterial endothelium was removed by rubbing the inner surface with thin surgical thread (o.d. ∼0.1 mm). Removal of the endothelium was assessed by the ability of 10 μM acetylcholine to relax constrictions induced by 1 μM phenylephrine. The experimental bath (volume 10 ml) was maintained at 37 ± 1°C. Physiological salt solution (PSS) contained: NaCl, 145.0 mM; KCl, 5.4 mM; CaCl2, 1.8 mM; MgCl2, 1.0 mM; HEPES, 5.0 mM; and glucose, 10.0 mM, pH adjusted to 7.4 with NaOH. For Ca++-free experiments, CaCl2 was replaced with equimolar MgCl2 and 1 mM EGTA was added to the solution. Isometric muscle tension was sampled and analyzed by a Macintosh computer (SE 30 and Power Macintosh 7200/90) via a Myo-Interface (model 500A; JP Trading, Aarhus, Denmark) and a MacLab interface (AD Instruments Pty Ltd, Castle Hill, Australia). Pulmonary artery rings were subjected to an initial tension of 25 mm Hg (3.3 kPa). Before experiments were carried out, arteries were constricted by high K (50 mM) several times to verify that the tissue was viable and to allow for tissue equilibration. All drugs were applied directly to the bath solution, and bath perfusion (2 ml/min) was stopped during the period of exposure to the drugs.
In experiments using A23187, A23187-induced responses were produced following the method described by Ishikawa et al. (1994), with minor modification. Pulmonary arteries were treated with A23187 (10 μM) in Ca++-free PSS for 5 min to allow sufficient incorporation of the ionophore in the smooth muscle membrane. Nifedipine (10 μM) was also present to avoid any l-type Ca++ channel activation. CaCl2 (stock solution 1 M) was then applied to the bath solution to deliver a final Ca++concentration of 2 mM (as calculated using EQCAL software; Biotools, Cambridge, UK) and the pH was readjusted to 7.4.
Data Analysis.
All data were sampled at a rate of 2.0 Hz and analyzed using the MacLab 3.4.2 software. Original tension,T, was normalized using eq. 1.
Estimates of the maximum response (Rmax) and IC50for inhibition of the ET-1-induced constriction were calculated for individual arteries using the Hill eq. 2.
Drugs.
ET-1, UTP, angiotensin II, niflumic acid, DIDS, nifedipine, nicardipine, iberiotoxin (Ibtx), glibenclamide, and A23187 were purchased from Sigma (Poole, Dorset, UK). NPPB was purchased from ICN Biomedicals (Thame, UK). Sarafotoxin S6c was donated by A. Davenport (University of Cambridge, Cambridge, UK). Stock solutions of niflumic acid (100 mM) and NPPB (10 mM) were made up in pure water with approximately equivalent amounts of NaOH. Stock solutions of A23187 (100 mM), nifedipine (100 mM), and DIDS (100 mM) were dissolved in DMSO. DIDS was prepared before every experiment. The concentration of DMSO was 0.5% throughout in this study. Vehicle controls showed that at the highest concentrations used, DMSO had no effect on resting tone or on the ET-1-induced constriction.
Results
Effect of Niflumic Acid, NPPB, and DIDS on Arteries Preconstricted with ET-1.
Initial experiments were carried out to obtain a concentration-response curve for ET-1. This revealed that a submaximal response would be elicited by 30 nM ET-1, the tension developed being 10.9 ± 2.1 mN/mm2 (n = 6). This concentration of ET-1 was routinely used in the experiments described below, unless stated otherwise.
ET-1 (30 nM) produced two types of constriction in rat small pulmonary arteries. In 40 out of 53 preparations a slowly developing constriction was induced, which reached a maximum that was sustained for the duration of exposure to ET-1 (up to 2 h; Fig.1a). In the remaining preparations (n = 13), the ET-1-induced constriction reached a maximum and then declined by 14.2 ± 3.1% to a plateau (Fig. 4b). The ET-1-induced constriction reversed on washing, but the rate of reversal was slow and incomplete even after 5 h.
Figure 1, b and c show the effects of cumulative application of niflumic acid (1–300 μM; n = 7) and NPPB (0.3–100 μM; n = 8) on arteries preconstricted with 30 nM ET-1. Clearly, niflumic acid and NPPB induced a concentration-dependent relaxation. The inhibitory effect of both niflumic acid and NPPB was reversed on washing, although it took over 1 h to restore the tension to control levels (Fig. 1, b and c, inset). The effects of a third and structurally distinct Cl− channel blocker were, however, quite different. Figure 1d shows that application of DIDS (10–500 μM) had little or no effect on the ET-1-induced constriction (n = 5). Figure2 shows a plot describing the concentration-relaxation relationship for niflumic acid, NPPB, and DIDS (n = 5–8). The data for niflumic acid and NPPB, but not DIDS, were well fitted by the Hill equation (see Materials and Methods), which gave an Rmax, IC50, and Hill coefficient of 68.4 ± 2.1%, 35.8 ± 5.5 μM, and 2.2, respectively, for niflumic acid, and 79.8 ± 5.7%, 21.1 ± 1.1 μM, and 3.5, respectively, for NPPB.
Effect of Pretreatment with Niflumic Acid, NPPB, and DIDS on ET-1-Induced Constriction.
Application of Cl− channel blockers to ET-1 preconstricted arteries gives (see above) an indication of their effects on the steady-state constriction, at which point the Ca++-activated Cl− current (ICl(Ca)) may have less influence than at the point of initiation of constriction, especially when one considers that ET-1 rapidly activates ICl(Ca) in isolated pulmonary artery smooth muscle (∼30 s; Salter and Kozlowski, 1996). We therefore studied the effects of preincubating the arteries with the Cl− channel blockers on the initial rising phase of a subsequent constriction to ET-1. Arteries were pretreated with niflumic acid, NPPB, or DIDS, respectively, for 10 min before ET-1 (30 nM) application. In general, the Cl− channel blockers had little effect on the resting tone, although two out of six arteries showed a small increase in resting tone following the application of 100 μM NPPB (Fig. 3b). Pretreatment with niflumic acid (10, 30, and 100 μM) and NPPB (3, 10, 30, and 100 μM) attenuated ET-1-induced muscle constriction in a concentration-dependent and reversible manner (Fig. 3, a and b). These results are summarized in Table 1. Neither niflumic acid nor NPPB had any effect on the time to half-maximum (T1/2) for the ET-1-induced constriction when compared with control. Furthermore, the degree of inhibition of the maximum constriction observed was similar to that observed when these blockers were tested against arteries preconstricted with ET-1 (Fig. 3d). In contrast, pretreatment with 500 μM DIDS had no effect on the maximum response to ET-1 but theT1/2 was reduced from 192.5 ± 55.8 s to 68.2 ± 16.6 s (n=6). This is, however, likely due to a nonspecific effect, because block ofICl(Ca) would be expected to slow the rising phase of constriction.
Effect of Ibtx and Glibenclamide on Niflumic Acid and NPPB-Mediated Relaxation.
Previous reports have suggested that niflumic acid may activate large conductance Ca++-activated K+(BKCa) channels (Ottolia and Toro, 1994; Greenwood and Large, 1995) and that NPPB may also activate ATP-sensitive K+ (KATP) channels (Kirkup et al., 1996). We therefore investigated whether the inhibitory effects of niflumic acid and NPPB were due to BKCa or KATP channel activation by selectively blocking these channels with Ibtx and glibenclamide, respectively. Figure 4a shows that in ET-1 (30 nM) preconstricted arteries 100 nM Ibtx failed to reverse the relaxation induced by 100 μM niflumic acid (n = 8). Ibtx itself had no effect on resting muscle tone (Fig. 4a, inset), whereas in two out of four muscles preconstricted with ET-1, Ibtx produced further constriction (Fig. 4b). Preapplication of Ibtx (Fig. 4b; n = 4) or glibenclamide 30 μM (Fig. 4c; n = 4) also failed to prevent the relaxation observed with 100 μM NPPB. It should be noted that glibenclamide itself (30 μM) and the combined application of glibenclamide and Ibtx (100 nM) had no effect on resting muscle tone (Fig. 4c, inset). These data suggest that the relaxations induced by niflumic acid and NPPB occur independently of either BKCaor KATP channel activation.
Effect of Nifedipine and Ca++-Free PSS on Niflumic Acid and NPPB-Mediated Relaxation.
One of the most common mechanisms by which an agonist causes constriction of vascular smooth muscle is by inducing membrane depolarization and Ca++ influx via VGCCs. If ET-1-mediated activation of Cl− channels produces sufficient membrane depolarization to open VGCCs, and niflumic acid and NPPB induce relaxation by blocking Cl− channels, then the relaxation induced by Cl− channel blockers should be similar to that produced by Ca++ channel antagonists such as nifedipine. This assumption would also apply if niflumic acid and NPPB had the capacity to block VGCCs directly. Figure5, a and c show that application of nifedipine (10 μM) reduced constriction induced by 30 nM ET-1 to only 94.2 ± 2.3% of the control (n = 9). Moreover, application of either niflumic acid (30 μM,n = 5) or NPPB (30 μM, n = 4) in the continued presence of nifedipine caused a further relaxation to 46.9 ± 6.2 and 23.0 ± 1.5% of control, respectively (Fig.5, ai, aii, and c). These results suggest that relaxation induced by niflumic acid and NPPB are unlikely to be due to the inhibition of Ca++ influx via VGCCs. We also investigated the effect of nifedipine (10 μM) pretreatment on the ET-1-induced constriction (Fig. 5aiii). Surprisingly, nifedipine (10 mM) did not alter the maximum tension or the T1/2 of the ET-1-induced constriction. The values for maximum tension were 11.0 ± 0.9 and 10.9 ± 2.1 mN/mm2 and forT1/2 were 236.7 ± 36.5 and 192.5 ± 55.8 in the presence and absence of nifedipine (10 μM), respectively. This suggests that the contribution of voltage-dependent Ca++ influx is small even during the rising phase of the response.
Support for the above conclusion was provided by experiments carried out in Ca++-free PSS (containing 1 mM EGTA), i.e., in the absence of any Ca++ influx. In these experiments, 100 nM ET-1 was used to preconstrict the pulmonary arteries, because insufficient tension could be generated by 30 nM ET-1. The maximum constriction evoked by 100 nM ET-1 was 3.7 ± 0.6 mN/mm2. Figure 5, b and c show that even in the absence of induced Ca++ influx, both niflumic acid (100 μM, n = 5) and NPPB (30 μM,n = 5) relaxed the constriction induced by ET-1 (100 nM) to 41.5 ± 9.6 and 40.1 ± 1.3% of control, respectively.
Effect of Niflumic Acid, NPPB, and DIDS on A23187-Induced Constriction.
To establish whether the relaxation induced by niflumic acid and NPPB was mediated via inhibition of signal transduction before or subsequent to any elevation of the intracellular free Ca++ concentration, the effects of these agents on constriction induced by the Ca++ ionophore, A23187, were examined. For the purposes of these studies, arteries were first pretreated with A23187 (10 μM) in Ca++-free PSS for 5 min followed by application of Ca++ to yield a final Ca++ concentration of 2 mM (see Materials and Methods). A23187 itself had virtually no effect on the resting tone in Ca++-free PSS. However, Fig.6a shows that when Ca++ was readmitted in the continued presence of A23187 (10 μM), pulmonary arteries constricted, generating a maximum tension of 9.4 ± 2.4 mN/mm2 (n = 6). Surprisingly, niflumic acid (n = 6) and NPPB (n = 5), but not DIDS (n = 4), relaxed pulmonary arteries preconstricted with A23187 (10 μM) in a reversible and concentration-dependent manner (Fig. 6, b-d). Figure7 shows the concentration-relaxation relationship for niflumic acid, NPPB, and DIDS. The data for niflumic acid and NPPB, but not DIDS, fit well to the Hill equation (seeMaterials and Methods), which gave values forRmax, IC50, and the Hill coefficient of 75.1 ± 4.3%, 18.0 ± 2.3 μM, and 1.3, respectively, for niflumic acid and 72.1 ± 8.2%, 8.8 ± 2.0 μM, and 1.8, respectively, for NPPB.
Nonspecific Relaxation Effect of Niflumic Acid on Sarafotoxin S6c- (STXS6c), UTP-, and Angiotensin II-Induced Constriction.
Figure8a shows that 30 pM STXS6c, a selective ETB receptor agonist (Williams et al., 1991), induced a constriction of 12.2 ± 1.1 mN/mm2(n = 6), equivalent in magnitude to that produced by 30 nM ET-1. In contrast to the constriction induced by ET-1, the STXS6c-induced constriction was not sustained but gradually decayed with a T1/2 of 58.4 ± 7.0 min. To avoid overestimating the magnitude of any relaxation effects, we therefore used only a single concentration of the chloride channel blockers. Figure 8, b-d show that nifedipine (10 μM) partially relaxed arteries preconstricted with 30 pM STXS6c to 75.0 ± 2.8% of control (n = 8). Even in the continued presence of nifedipine (10 μM), however, both niflumic acid (30 μM; Fig. 8b) and NPPB (30 μM; Fig. 8d) relaxed pulmonary arteries preconstricted with STXS6c to 16.0 ± 5.1% (n = 4) and 5.6 ± 2.3% (n = 4) of control, respectively (Fig. 8d). In contrast, DIDS (500 μM) had no effect on the STXS6c-induced constriction (n = 4; data not shown).
To verify whether the effects of niflumic acid and NPPB used in this study were agonist specific or not, we examined their effects on UTP- and angiotensin II-induced constriction. UTP (1 mM) induced a sustained constriction of rat small pulmonary arteries. Figure9, a and c show that niflumic acid (30 μM) and NPPB (30 μM) reduced the UTP-induced constriction to 32.4 ± 8.8 and 28.9 ± 6.5% of control (n = 6). Their potency was higher than that of nifedipine, which reduced UTP-induced constriction to 66.1 ± 14.3% of control (n = 5, data not shown). Niflumic acid and NPPB also relaxed constriction evoked by 30 nM angiotensin II (Fig. 9, b and d). Nicardipine (1 μM) reduced the angiotensin II-induced constriction to 50.8 ± 6.3% of control (n = 10). The nicardipine-insensitive component of the angiotensin II-induced constriction was significantly inhibited by niflumic acid (n = 6) and NPPB (n = 4) to 3.2 ± 1.3 and 2.7 ± 1.6% of control in rat small pulmonary arteries.
Discussion
The purpose of the present study was to determine whether Cl− channels play a significant role in ET-1- and STXS6c-induced constriction of rat small pulmonary arteries. Our findings suggest that Cl− channel activation does not play a significant role in mediating the constriction evoked by either ET-1 or STXS6c in this tissue. Furthermore, we conclude that the Cl− channel blockers niflumic acid and NPPB relax the ET-1- and STXS6c-induced constriction of pulmonary arteries by a mechanism independent of Cl− channel inhibition.
Cumulative application of niflumic acid and NPPB relaxed rat pulmonary arteries preconstricted with ET-1 in a concentration-dependent and reversible manner. The threshold concentration of the induced relaxation was approximately 10 μM for both niflumic acid and NPPB. This is within the concentration range of niflumic acid used to confirm the involvement of ICl(Ca) in agonist-induced constriction of pulmonary arteries in previous studies (Wang et al. 1997; Yuan, 1997). Another Cl−channel blocker, DIDS, was ineffective in spite of the fact that it has previously been shown to block ICl(Ca)in smooth muscle cells from a variety of tissues including rat pulmonary arteries (Amédée et al., 1990; Clapp et al., 1996; Large and Wang, 1996; Yuan, 1997). In contrast, however, DIDS has been shown to relax the phenylepherine-induced constriction of rat small pulmonary arteries (Yuan, 1997). ICl(Ca)activation may, therefore, contribute to the constriction induced by vasoconstrictors other than ET-1. In suppport of this conclusion, similar results to those described above were obtained in experiments in which pulmonary arteries were preincubated with the Cl− channel blockers before ET-1 application. In this series of experiments, niflumic acid and NPPB failed to alter theT1/2 for ET-1-induced constriction. However, the ET-1-induced constriction was inhibited to a similar degree to that observed in arteries preconstricted with ET-1. Again, in marked contrast, preincubation with DIDS did not inhibit the ET-1-induced constriction of rat pulmonary arteries: observations that suggest that ICl(Ca) activation is not involved in ET-1-induced constriction and that NPPB and niflumic acid may inhibit constriction through some other means. In suppport of this notion, the effects of niflumic acid and NPPB seem to be unrelated to the nature of the agonist used and, therefore, the membrane receptor activated since niflumic acid and NPPB relax STXS6c-, UTP-, and angiotensin II-induced constriction in rat small pulmonary arteries.
Additional support for a mechanism distinct from the block ofICl(Ca) comes from the markedly different recovery times for the effects of niflumic acid and NPPB. Generally, it takes approximately 5 min for complete recovery ofICl(Ca) after washing off niflumic acid and NPPB (Kirkup et al. 1996; Salter and Kozlowski, 1997; Wang et al. 1997), whereas in the present investigation it took around 1 h to recover the ET-1-induced constriction after washing off these Cl− channel blockers. This slow time course of recovery from inhibition by niflumic acid has also been observed in studies of the role of ICl(Ca) in constriction evoked by other agonists (Criddle et al., 1996; Yuan, 1997), where complete recovery was not observed following 25 min of washing. Of further interest in this respect are the findings of Wang et al. (1997), who showed that niflumic acid not only inhibits agonist-induced pulmonary artery constriction, but also inhibits constriction induced by elevating extracellular K+ (Wang et al., 1977). These authors conclude that inhibition of the K+-induced contraction was due either to the block of some contribution of ICl(Ca) to depolarization evoked contraction or to nonspecific effects of niflumic acid. In contrast, Criddle et al. (1996) observed no inhibition of K+-induced contraction of rat aorta with 10 μM niflumic acid, and Yuan (1997) showed that niflumic acid (50 μM) had no effect on high K-induced contraction of rat pulmonary arteries. These discrepancies may be due to the incubation time required (≈5 min) before the onset of niflumic acid-induced inhibition.
It is arguable that the niflumic acid- and NPPB-induced relaxation of preconstricted pulmonary arteries could be mediated via the activation of K+ channels. Previous electrophysiological studies (Ottolia and Toro, 1994; Greenwood and Large, 1995) have demonstrated that the fenamate family, which includes niflumic acid, can activate BKCa channels. This effect is also exhibited by NPPB, which has been shown to activate KATP channels in rat portal vein (Kirkup et al., 1996). Such effects could produce membrane hyperpolarization, resulting in closure of VGCCs and ultimately relaxation of smooth muscle. However, in the present investigation, Ibtx, one of the most potent and specific BKCa channel blockers, had no effect on the relaxation induced by niflumic acid or NPPB. Moreover, the NPPB-induced relaxation was unaffected by glibenclamide. Thus, it is unlikely that the niflumic acid and NPPB-induced relaxation of pulmonary arterial smooth muscle involves activation of either BKCa or KATP channels.
It is possible that the niflumic acid- and NPPB-induced relaxation of preconstricted rat pulmonary arteries involve either direct or indirect inhibition of VGCCs. To test this possibility, we studied the effects of nifedipine on ET-1-induced constriction and on the inhibitory action of niflumic acid and NPPB. However, we discovered that nifedipine had only a marginal effect on the ET-1-induced constriction, and that application of niflumic acid and NPPB in the continued presence of nifedipine produced a much greater degree of relaxation. Although it is clear from our previous studies (Salter and Kozlowski, 1996) and those of others (Miyoshi et al., 1992; Van Renterghem and Lazdunski, 1993) that ET-1-induced membrane depolarization in smooth muscle cells may activate l-type Ca++ channels, it is unlikely that this mechanism plays a primary role in mediating ET-1-induced constriction of rat pulmonary arteries. Furthermore, when pulmonary arteries were bathed in Ca++-free PSS to eliminate the possibility that ET-1-stimulated Ca++ influx contributed to the constriction, niflumic acid and NPPB were still able to produce a substantial relaxation of ET-1-preconstricted arteries. These data, however, do not rule out the possibility that niflumic acid and NPPB may act as antagonists of ET receptors, or inhibitors of ET-receptor mediated activation of second messenger pathways. We therefore used the Ca++ ionophore, A23187, to induce constriction in a manner that would bypass receptor activation and any receptor-dependent signal transduction pathways. Surprisingly, niflumic acid and NPPB, but not DIDS, relaxed pulmonary arteries preconstricted with A23187 to a similar degree to that following ET-1-induced constriction. Comparison of the Hill coefficients for niflumic acid (∼1) and NPPB (∼2) under these conditions, suggests that a less-complex mechanism than that observed in ET-1-preconstricted arteries may be involved. In fact, niflumic acid may affect only one Ca++-dependent contractile process, given that the fitted Hill coefficient is close to unity. Taken together, these observations suggest that niflumic acid and NPPB inhibit contraction downstream of Ca++ influx and intracellular Ca++ release pathways.
Our observations clearly differ from a recent study in rat cerebral arteries, which showed that IAA-94 and DIDS, but not niflumic acid, cause hyperpolarization and dilatation of pressurized (80 mm Hg) cerebral arteries (Nelson et al., 1997). Nelson et al. (1997) conclude that the observed vasodilation is due to Cl−channel block, and that Cl− channels are active and contribute to the membrane potential in cerebral artery smooth muscle under quasi-physiological transmural pressure (around 80 mm Hg). Furthermore, they conclude that the inhibition of Cl− channels by IAA-94 or DIDS promotes the observed membrane hyperpolarization, which would lead to the closure of VGCCs, reduced Ca++ influx, and dilation. Our findings suggest that neither ICl(Ca)nor any other DIDS-sensitive Cl− current is active in pulmonary artery smooth muscle under the quasi-physiological transmural pressures (25 mm Hg) used in the present study (because DIDS had no effect on resting or ET-1-induced tone). It is possible that these discrepancies may be explained by differences in the basic physiology of pulmonary and cerebral blood vessels. Indeed, under physiological conditions, the intravascular pressure of pulmonary arteries is markedly lower (15–30 mm Hg) than that of cerebral arteries (Grover et al., 1983; Leach et al., 1992; Evans et al., 1996). Furthermore, although previous electrophysiological studies have demonstrated that ET-1 may activateICl(Ca) and thereby promote membrane depolarization in isolated rat pulmonary artery smooth muscle cells, it is unlikely that this depolarization plays an important role in the ET-1-induced constriction. However, it is clear that Cl− channels may play some role in mediating pulmonary artery constriction in response to other agonists (Wang et al. 1997; Yuan, 1997).
In conclusion, we propose that Cl− channel activation does not play an essential role in either ET-1- or STXS6c -induced constriction of rat small pulmonary arteries. Our findings also suggest that, at least in rat pulmonary arteries, the Cl− channel blockers niflumic acid and NPPB, but not DIDS may induce a vasorelaxation by inhibiting Ca++-dependent activation of the contractile process. This result raises serious doubts over the suitability of agents like niflumic acid and NPPB as pharmacological tools for examining Cl− channel involvement in physiological processes in the absence of rigorous control experiments.
Acknowledgments
We thank Dr. T. C. Cunnane for giving us access to “MacLab” and Drs. N. Teramoto and L. Smith for helpful comments on this work. Roland Z. Kozlowski is a British Heart Foundation Lecturer. A. Mark Evans is a Wellcome Career Development Research Fellow.
Footnotes
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Send reprint requests to: Kenichi Kato, University Department of Pharmacology, University of Oxford, Mansfield Road, Oxford, OX1 3QT, UK. E-mailKen.Kato{at}pharm.ox.ac.uk
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↵1 This research was supported by the British Heart Foundation, the Medical Research Council, and the Royal Society.
- Abbreviations:
- ET-1
- endothelin-1
- STXS6c
- sarafotoxin S6c
- NPPB
- 5-nitro-2-(3-phenylpropylamino)-benzoic acid
- DIDS
- 4,4′-diisothiocyanatostilbene-2,2′-disulphonic acid
- VGCC
- voltage-gated Ca++
- ICl(Ca)
- Ca++-activated Cl− current
- IKV
- delayed rectifier K+current
- Received April 23, 1998.
- Accepted September 14, 1998.
- The American Society for Pharmacology and Experimental Therapeutics