EndothelinB Receptors in Rabbit Pulmonary Resistance Arteries: Effect of Left Ventricular Dysfunction

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Vol. 284, Issue 3, 895-903, March 1998

Endothelin_B Receptors in Rabbit Pulmonary Resistance Arteries: Effect of Left Ventricular Dysfunction¹

Cheryl C. Docherty and Margaret R. Maclean

Clinical Research Initiative in Heart Failure, Division of Neuroscience and Biomedical EC₅₀ Systems, Institute of Biomedical pEC₅₀ and Life Sciences, University of Glasgow, Glasgow, Scotland

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

The endothelin (ET) receptor that mediates vasoconstriction of the isolated rabbit pulmonary resistance artery was characterizedusing selective ET receptor agonists and antagonists. We alsoexamined changes in ET-induced vasoconstriction brought aboutby left ventricular dysfunction using the rabbit coronary ligationmodel. The rank order of potency for contraction was sarafotoxinS6c (S6c) > ET-1 = ET-3, which is characteristic of an ET_B-likereceptor. The combined ET_A/ET_B receptor antagonist SB209670 (1µM) antagonized responses to ET-1 and S6c with estimated pK_bvalues of 6.8 ± 0.2 and 7.8 ± 0.2, respectively. BQ788 (1 µM)antagonized responses to S6c and ET-3 (but not ET-1) with estimatedpK_b values of 7.1 ± 0.2 and 6.6 ± 0.1, respectively. The ET_A receptorantagonist FR139317 (1 µM), either alone or in combination withBQ788, did not inhibit responses to ET-1. The profile of the ET-1response was not altered by left ventricular dysfunction. In controlrabbits, the inhibitor of nitric oxide synthase N-nitro-L-arginine methyl ester (100 µM) had no significant effecton the potency of either ET-1 or S6c. In the coronary-ligatedrabbits, however, it significantly increased the potency (10-15-fold)of both ET-1 and S6c. These results suggest that the ET receptorthat mediates contraction in rabbit pulmonary resistance arterieshas the characteristics of an ET_B-like receptor. The responsesto ET-1 are not altered by LVD but may be modified by increasedrelease of nitric oxide.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

The ETs and sarafotoxins are a family of potent vasoconstrictor peptides (Inoue et al., 1989; Kloog and Sokolovsky, 1989).Two subtypes of mammalian ET receptor have been cloned and sequenced.The first was denoted ET_A and demonstrates selectivity for ET-1over ET-3 (Arai et al., 1990). The other receptor, ET_B, is non-isopeptide-selective(Sakurai et al., 1990). Both receptors have been shown to mediatecontraction, but the ET_B receptor may also mediate vasodilationvia endothelial release of NO (Masaki et al., 1991). The contractileand vasodilator ET_B receptors have been termed ET_B2 and ET_B1,respectively (Sokolovsky et al., 1992; Warner et al., 1993). Aputative ET_C receptor, with high affinity for ET-3, has been clonedfrom the dermal melanophores of Xenopus laevis (Karne et al.,1993). Although there is pharmacological evidence for such a receptorin vascular tissue, a mammalian homolog has not yet been cloned(Masaki et al., 1992; Douglas et al., 1995).

ETs have been implicated in many pathophysiological conditions, including PHT. Elevated circulating ET-1 levels have beenreported in patients with both primary and secondary PHT (Stewartet al., 1991). Increased plasma levels also occur secondary toleft heart dysfunction, congenital heart defects and cardiac surgery,and they are positively correlated with the degree of PHT andnegatively correlated with prognosis (Cody et al., 1992; Yoshibayashiet al., 1991). Kiowski et al., (1995) reported that the ET_A/ET_Breceptor antagonist bosentan decreased pulmonary vascular resistancein heart failure patients. Recently, there has been much interestin ET receptor antagonists as possible therapeutic agents forthe treatment of cardiovascular disease, including PHT. For thisreason, we recently characterized the ET receptors that mediatevasoconstriction in human PRAs (McCulloch et al., 1996) as wellas in rat PRAs (MacLean et al., 1994; McCulloch, et al., in press)and investigated how responses to ET-1 are altered by hypoxia-inducedPHT (McCulloch and MacLean, 1995; MacLean et al., 1995; McCullochet al., in press). These studies demonstrated that both ET_A andET_B receptors mediate contraction in PRAs. ET_A and ET_B receptorsalso mediate contraction in large rabbit pulmonary arteries (LaDouceuret al., 1993; Hay et al., 1996). Because it is the PRAs that arethought to be functionally important in resistance changes observedin PHT, the main aim of this study was to characterize the ETreceptors that mediate vasoconstriction in rabbit PRAs.

The development of PHT secondary to chronic heart failure, induced by coronary ligation in the rat, can be ameliorated bylong-term treatment with an ET_A receptor antagonist (Sakai etal., 1996). We have recently demonstrated that LVD, induced bycoronary ligation, in the rabbit causes an increase in right ventricularweight, lung weight and the pulmonary artery pressure and muscularizationof prealveolar pulmonary arterioles (Deuchar et al., in press).A secondary aim of this study was therefore to determine whetherthere were any changes in ET-mediated vasoconstriction in thePRAs secondary to LVD in this model.

There is evidence that NOS may be up-regulated in patients with heart failure, and inhibition of NOS increased pulmonary vascularresistance in these patients (Habib et al., 1994). Therefore,we investigated the presence of basal and/or agonist-induced NOrelease in the sham-operated and coronary-ligated rabbit PRAsby examining the effect of the NOS inhibitor L-NAME on responsesto ET-1 and S6c.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

The rabbit model. Lungs were obtained from the rabbit coronary-ligation model of LVD that has been extensively characterized (Pye et al., 1996;Deuchar et al., in press). Briefly, the left circumflex coronaryartery of New Zealand White rabbits is fully ligated to producean acceptable area of infarction. The infarct area was assessedhistologically in a cohort of rabbits and was 16 ± 2% for n =6 rabbits (for methodology, see Pye et al., 1996). Because ofthe lack of collateral circulation of the rabbit, there is noreduction in this infarct size with time (Pye et al., 1996). Age-matchedanimals undergo the same procedures as the experimental animalsexcept that the ligatures placed around the coronary artery arenot secured. These animals are subsequently referred to as "sham-operated"or control animals. The ejection fraction of the rabbits usedin the studies described here was assessed by echocardiographyas previously described (Pye et al., 1996). In a cohort of therabbits used for the present study, the ligation procedure reducedthe ejection fraction from 74.3 ± 1.3% to 44.3 ± 0.8% (n = 12,P < 0.0001). We have previously demonstrated changes in this modelthat are consistent with the onset of PHT (Deuchar et al., inpress). In the rabbits used in this study, the ratio of rightventricular weight to body weight was increased from 0.42 ± 0.01to 0.51 ± 0.02 (n = 25, P < 0.001) and lung weights increasedfrom 12.0 ± 0.3 g to 13.1 ± 0.3 (n = 50, P < 0.5). We have alsodemonstrated that there is small pulmonary artery vascular remodelingin these rabbits that is consistent with the onset of PHT (Deucharet al., 1997).

PRAs. Animals were killed by sodium pentobarbitone 8 weeks after the procedure. The lungs were removed, and intralobar PRAs (I.D.~ 150 µm) were dissected out and cleaned of surrounding parenchyma.These were mounted as ring preparations (~ 2 mm long) on a wiremyograph, bathed in Krebs solution at 37°C and bubbled with 16%O₂/5%CO₂balance N₂. This gave a final bath O₂ concentration (measuredwith an oxygen electrode and blood gas analyser) of approximately120 mm Hg and CO₂ tension of approximately 35 mm Hg to yield valuesequivalent to those found in pulmonary arteriolar blood. Vesselswere then tensioned to give a transmural pressure equivalent toapproximately 16 mm Hg, which is similar to in vivo pressuresof pulmonary arterioles.

Experimental protocol. After a 1-h equilibration period, the response of the PRAs to 50 mM KCl was determined twice. Cumulative concentration-responsecurves (CCRCs) were then constructed to ET-1, ET-3 or S6c (1 pM-0.3µM). Some vessels were preincubated with ET receptor antagonists(FR 139317, BQ 788 or SB 209670) for 45 min before the constructionof the CCRC, and some were preincubated with L-NAME for 30 min.For comparison, CCRCs were also constructed to 5-hydroxytryptamine(5-HT) and KCl. We analyzed endothelial-dependent vasodilationby preconstricting vessels with the thromboxane mimetic U46619(30 nM) and constructing CCRCs to ACh (0.1 nM-1 µM), ET-1, ET-3,S6c (all 0.01 pM-0.01 µM), substance P (1 pmol-0.1 µM), bradykinin(0.1 nM-1 µM), the calcium ionophore A23187 (0.1 nM-1 µM), histamine(0.1 nM-1 µM), $alpha$ -methyl 5-HT (0.1 nM-1 µM) and ionomycin (0.1nM-1 µM). Endothelium-independent vasodilation was assessed bypreconstricting with U46619 and constructing CCRCs to SNP.

Drugs and solutions. The composition of the Krebs/bicarbonate saline (pH 7.4) was as follows (in mM): NaCl 118.4, NaHCO₃ 25, KCl 4.7, KH₂PO₄ 1.2,MgSO₄ 0.6, CaCL₂ 2.5, glucose 11, EDTA 23. The following drugswere used: ET-1 (Thistle Peptides, Glasgow, Scotland), ET-3 (PeninsulaLaboratories, St. Helens, England), BQ788 (N-cis-2,6-dimethylpiperidinocarboxyl-L-g-methylleucyl-D-I-methocarbonyltrypophanyl-D-norleucine)(Peptide International, Louisville, KY), FR139317((R)2-[(R)-2-[(S)-2-[[1-(hexahydro-1H-azepinyl)]carbinyl]amino-4-methylpertanoyl]amino-3-[3-(1-methyl-1Hindoyl)]propionyl]amino-3-(2-pyridyl)propionicacid (Neosystems, France), SB209670 ([(+)-(1S, 2R, 3S)-3-()1-(3,4-methylenedioxyphenyl)-5-(prop-1-yloxy)indene-2-carboxylicacid] (SmithKline Beecham Pharmaceuticals, King of Prussia, PA), $alpha$ -methyl-5-HT (Semat, St. Albans, England). S6c, L-NAME, U46619(9,1-dideoxy-11 $alpha$ ,9 $alpha$ -epoxymethano-prostaglandin F₂), ACh chloride,substance P, sodium nitroprusside, bradykinin, histamine diphosphate,ionomycin and A23187 were supplied by Sigma, Poole, UK. Stocksolutions of S6c were prepared in 0.1% acetic acid and those ofBQ788 in 0.1% dimethyl sulfoxide. All other drugs and dilutionswere prepared in distilled water.

Data analysis. pEC₅₀ values were calculated by computer interpolation from individual CCRCs. The CCRCs were not subjected to any curve-fittingprogram, because they were neither typically sigmoidal nor biphasicand there are no suitable curve-fitting programs that accommodatesuch curves, i.e., the first component was less than 30% of themaximal response. In addition, responses to S6c were "droppedoff" at high concentrations, a phenomenon that curve-fitting cannotaccommodate.

Statistical comparison of the means of groups of data was made by two-way analysis of variance (ANOVA); P < 0.05 was consideredstatistically significant. Throughout, data are expressed as mean± S.E.M., and n/n = number of ring preparations/number of animals.CCRCs for vasoconstriction are shown either as responses expressedas a percent of maximal response to agonist or as a percent ofthe response to 50 mM KCl. The CCRC for SNP is shown as the relaxationas a percent of the maximal tone induced by U46619. Wherever possible,pK_b values were estimated for a single stated concentration ofantagonist, assuming that pK_b = $-$ log[antagonist]/(X $-$ 1), whereX is the ratio of the agonist concentration required to elicit50% of the maximal contraction in the presence of the antagonistto the concentration required in its absence (Arunlakshana andSchild, 1959

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Responses to KCl

LVD had no effect on the sensitivity of the PRAs to KCl (fig. 1). The maximal responses to KCl in the control animal vesselswere not significantly different from those in the vessels removedfrom the coronary-ligated, LVD animals (336 ± 56 mg wt. (n = 12/7)vs. 358 ± 103 mg wt. (n = 9/7)).

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Fig. 1. Cumulative concentration-response curves to KCl in PRAs from sham-operated ( $open circle$ n/n = 6/3) and coronary-ligated ( $bullet$ n/n = 10/5)rabbits. Data are expressed as a percentage of their own maximalresponse. Each point represents mean ± S.E.M. n/n: number of preparations/numberof animals.

Responses to ET-1, S6c and ET-3

Figure 2A and B demonstrates CCRCs to ET-1, S6c and ET-3 in sham-operated and coronary-ligated rabbits, respectively. TheCCRCs can be seen to contain a relatively shallow component atthe lower concentrations of ET agonists. All three ET receptoragonists were potent vasoconstrictors of the rabbit PRAs; EC₅₀values are summarized in table 1. The rank order of potency forthese peptides was S6c > ET-1 = ET-3. No significant differencein agonist potency was noted between the sham-operated and coronary-ligatedrabbit vessels. The values for the maximal contractions are shownin table 2. In the sham-operated rabbits, the maximal contractionto S6c was less than that of ET-3 and not quite statisticallydecreased compared with ET-1 (P < 0.06). However, in all vesselstested, the S6c CCRC exhibited a sudden "drop-off" at high concentrations.The maximal responses to S6c and ET-3 were less than that to ET-1in the coronary-ligated rabbit PRAs, and the maximal responsesto ET-3 in these rabbits were significantly reduced compared withthe response in the sham-operated rabbit vessels.

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Fig. 2. A) Responses to endothelin-1 ( $open circle$ , n/n = 8/6), endothelin-3 ( $triangle$ , n/n = 10/9) and sarafotoxin S6c ( $square$ , n/n = 10/9) in PRAs fromsham-operated rabbits. B) Responses to endothelin-1 ( $bullet$ , n/n =12/7), endothelin-3 ( $black-triangle$ , n/n = 9/6) and sarafotoxin S6c ( $black-square$ , n/n= 11/7) in PRAs from coronary-ligated rabbits. Data are expressedas a percentage of the response to 50 mM KCl. Each point representsmean ± S.E.M. n/n: number of preparations/number of animals.

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TABLE 1
EC₅₀ values for ET-1, S6c and ET-3 in the absence and presence of antagonists, in PRAs from sham-operated rabbits and rabbitswith LVD

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TABLE 2
Maximal contraction to ET agonists, as percent of contraction to 50 mM KCl, in PRAs from sham-operated rabbits and rabbitswith LVD

Effect of Antagonists on ET Receptor-Mediated Contraction in Control Rabbits

FR139317 (vs. ET-1). The selective ET_A receptor antagonist FR139317 (1 µM) failed to inhibit the ET-1-evoked response (table 1; fig. 3A).

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Fig. 3. A) Cumulative concentration-response curves to endothelin-1 ( $open circle$ , n/n = 8/6) and endothelin-1 in the presence of 1 µM FR139317( $bullet$ , n/n = 7/6). B) Cumulative concentration-response curves toET-1 ( $open circle$ , n = 8/6), in the presence of 1 µM BQ788 ( $black-triangle$ , n/n = 6/5)and in the presence of 1 µM FR139317 and 1 µM BQ788 ( $black-square$ , n/n =7/6). Data are expressed as a percentage of the response to 50mM KCl. Each point represents mean ± S.E.M. n/n: number of preparations/numberof animals.

BQ788 (vs. ET-1). BQ788 (1 µM) inhibited the response to ET-1 up to 1 nM in that it removed the shallow component of the CCRC (fig. 3B). Responsesto higher concentrations were not inhibited by BQ788. There wasno significant change in the magnitude of responses to any concentrationof ET-1.

BQ788 + FR139417 (vs. ET-1). FR139317 (1 µM) did not influence the effect of BQ788 (1 µM, fig. 3B).

BQ788 (vs. S6c). BQ788 (1 µM) inhibited the S6c-induced response (table 1; fig. 4A). The estimated pK_b value was 7.1 ± 0.2. The maximal responseto S6c was increased by BQ788 (fig. 4A).

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Fig. 4. A) Cumulative concentration-response curves to S6c ( $square$ , n/n = 10/9) and in the presence of 1 µM BQ788 ( $black-triangle$ , n/n = 7/7). B) Cumulativeconcentration-response curves to endothelin-3 ( $triangle$ , n/n = 10/9)and in the presence of 1 µM BQ788 ( $black-triangle$ , n/n = 10/9). Data are expressedas a percentage of the response to 50 mM KCl. Each point representsmean ± S.E.M. n/n: number of preparations/number of animals.

BQ788 (vs. ET-3). BQ788 (1 µM) inhibited responses to ET-3 (table 1; fig. 4B). The estimated pK_b value was 6.6 ± 0.1.

SB209670 (vs. ET-1). 0.1 µM SB209670 had no effect on responses to ET-1 in the PRAs from the sham-operated rabbits. However, when present at 1µM, it did inhibit responses (see table 1; fig. 5A). SB209670inhibited ET-1 > 30 nM, and a shallow component of the CCRC toET-1 was uncovered in the presence of SB209670 (fig. 5A). An estimatedpK_b value for SB209670 was determined at the EC₅₀ level of theET-1-induced response (6.8 ± 0.2). Maximal responses were notaffected by SB209670.

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Fig. 5. A) Cumulative concentration-response curves to ET-1 ( $open circle$ , n/n = 8/6), in the presence of 0.1 µM SB 209670 ( $bullet$ , n/n = 6/6) andin the presence of 1 µM SB 209670 ( $black-square$ , n/n = 8/7). B) Cumulativeconcentration-response curves to sarafotoxin S6c ( $square$ , n/n = 10/9),in the presence of 0.1 µM SB 209670 ( $bullet$ , n/n = 7/6) and in thepresence of 1 µM SB 209670 ( $black-square$ , n/n = 7/6). Data are expressedas a percentage of the response to 50 mM KCl. Each point representsmean ± S.E.M. n/n: number of preparations/number of animals.

SB209670 (vs. S6c). SB209670 (1 µM) produced a concentration-dependent inhibition of responses to S6c, and the estimated pK_b value at the EC₅₀value of the S6c-induced response was 7.8 ± 0.2 (fig. 5B).

Effect of Antagonists on ET Receptor-Mediated Contraction in Rabbits with LVD

The potency of SB209670 (1 µM) on the response to S6c in the coronary-ligated rabbits was not so profound as in the sham-operatedrabbits (table 1). Indeed, the estimated pK_b value was significantlyless at 6.7 ± 0.1 (1 µM SB209670, P < 0.0001). There were no otherdifferences in the profile of antagonist effects.

Effect of LVD on 5-HT-Induced Contraction

The potency of 5-HT did not differ significantly between the control group (EC₅₀: 6.1 ± 0.2, n = 7 vessels from 6 rabbits)and the LVD group (EC₅₀: 6.1 ± 0.1, n = 7 vessels from 5 rabbits,fig. 6). The maximal response is reduced by ~30% (P < 0.05).

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Fig. 6. Cumulative concentration-response curves to 5-hydroxytryptamine in PRAs from sham-operated ( $open circle$ , n/n = 7/6) and coronary-ligated( $bullet$ , n/n = 7/5) rabbits. Data are expressed as a percentage ofthe response to 50 mM KCl. Each point represents mean ± S.E.M.n/n: number of preparations/number of animals.

L-NAME (vs. ET-1). i) Sham-operated control rabbits. Inhibition of NOS synthase with 100 µM L-NAME had no effect on responses to ET-1 (fig. 7A; table 3).

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Fig. 7. A) Sham-operated rabbits. Cumulative concentration-response curves to ET-1 ( $open circle$ , n/n = 8/6) and in the presence of 100 µM L-NAME( $bullet$ , n/n = 9/7). B) LVD rabbits. Cumulative concentration-responsecurves to ET-1 ( $open circle$ , n/n = 12/7) and in the presence of 100 µM L-NAME( $bullet$ , n/n = 7/6). Data are expressed as a percentage of the responseto 50 mM KCl. Each point represents mean ± S.E.M. n/n: numberof preparations/number of animals.

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TABLE 3
EC₅₀ values for ET-1 and S6c, in the absence and presence of 100 µM L-NAME, in PRAs from sham-operated rabbits and rabbitswith LVD

ii) Coronary artery coronary-ligated LVD rabbits. L-NAME (100 µM) caused a significant increase in the potency of ET-1 (fig.7B; table 3).

L-NAME vs. S6c) i) Sham-operated control rabbits. Inhibition of NOS synthase with 100 µM L-NAME had no effect on the potency of S6c, and maximal contraction to S6c was increased(67.9 ± 8.2 vs. 101.8 ± 13.7, P < 0.05; fig. 8A; table 3).

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Fig. 8. A) Sham-operated rabbits. Cumulative concentration-response curves to sarafotoxin S6c ( $square$ , n/n = 10/9) and in the presenceof 100 µM L-NAME ( $bullet$ , n/n = 9/7). B) LVD rabbits. Cumulative concentration-responsecurves to sarafotoxin S6c ( $square$ , n/n = 12/7) and in the presenceof 100 µM L-NAME ( $bullet$ , n/n = 7/6). Data are expressed as a percentageof the response to 50 mM KCl. Each point represents mean ± S.E.M.n/n: number of preparations/number of animals.

ii) Coronary artery coronary-ligated LVD rabbits. L-NAME (100 µM) caused a significant increase in the potency of S6c (fig.8B; table 3).

L-NAME had no effect on responses to KCl (data not shown).

Endothelium-Dependent Vasodilation

We found no evidence for endothelium-dependent vasodilation using any of the agents in either the sham-rabbit vessels or thecoronary-ligated rabbit vessels.

Endothelium-Independent Relaxation: SNP

The thromboxane mimetic U46619 (30 nM) produced the same degree of preconstriction in the control group (54.5 ± 7% of responseto 50 mM KCl, n = 14 vessels from six rabbits) and in the LVDgroup (48.6 ± 5% of response to 50 mM KCl, n = 14 vessels fromseven rabbits). The rabbits with LVD were less sensitive to therelaxant effects of SNP (EC₅₀: 6.8 ± 0.1) than their controls(EC₅₀: 7.3 ± 0.2, P < 0.05) although the maximal response to SNPwas unaffected (fig. 9).

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Fig. 9. Vasodilation induced by SNP in PRAs from sham-operated ( $open circle$ , n/n = 14/6) and coronary-ligated ( $bullet$ , n/n = 14/7) rabbits. Vasodilationis expressed as a percentage of the preconstricted tone inducedby 30 nM U46619. Each point represents mean ± S.E.M. n/n: numberof preparations/number of animals.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

The rank order of potency for the ET agonists in all vessels studied was S6c > ET-1 = ET-3 rabbit PRAs. This is indicativeof vasoconstriction being mediated by ET_B-like receptors, as hasbeen previously shown in the larger pulmonary artery of the rabbit(Fukuroda et al., 1994a; Hay et al., 1996). The results show thatSB209670 has estimated pK_b values of 6.8 and 7.8 against ET-1and S6c, respectively, in the sham-operated rabbit pulmonary arterioles.Hay et al. (1996) have shown that SB209670 has similar pK_b values(6.7 and 7.7) against responses to ET-1 and S6c, respectively,in large rabbit pulmonary arteries. Ohlstein et al. (1994b) alsoshowed that SB209670 has a pK_b value of 9.4 against ET_A-mediatedresponses in the rat aorta. This confirms that, in our study,SB209670 is acting as an antagonist against an ET_B receptor inthe rabbit PRAs and this SB209670-sensitive receptor has a pharmacologicalprofile similar to that in the larger pulmonary arteries. As describedin "Results," the shallow component of the CCRC to ET-1 was resistantto SB209670 and was more obvious in the presence of SB209670.This may suggest that responses to ET-1 are not mediated by ahomogeneous ET_B population, an interpretation consistent withthe observations and conclusions of Hay et al. in the large rabbitpulmonary artery.

The ET_B receptor antagonist BQ788 removed the initial "shallow component" of the ET-1 CCRC but failed to affect the rest ofthe CCRC. It did, however, inhibit responses to both S6c and ET-3,with estimated pK_b values of 7.1 and 6.6, respectively. Again,this phenomenon was observed by Hay et al. (1996) in the largerrabbit pulmonary arteries, where the pK_b values were 6.2 and 5.1for S6c and ET-3, respectively, whereas there was no effect onET-1. These authors concluded that the ET_B receptors in rabbitlarge pulmonary arteries are not sensitive to BQ788. It wouldappear, therefore, on the basis of both agonist and antagonistinteractions, that the ET_B receptor in the large and small pulmonaryarteries are pharmacologically similar.

The response to S6c in the rabbit PRAs demonstrated a "drop-off" at higher concentrations. We see a similar phenomenon inthe responses to S6c in rat PRAs (MacLean et al., 1994; McCullochand MacLean, 1995). This effect is not affected by administrationof L-NAME in either species and hence is not due to NO production.We attribute this to a desensitization of the receptor, becauseif we raise the tone of these vessels with U46619 and administerone dose of a high concentration of S6c, we obtain a contractionand not a vasodilation (C.C. Docherty and M.R. MacLean, unpublishedobservation).

The present results show that the CCRCs to ET-1 include a "shallow component" at lower concentrations of ET-1. We have previouslyfound similar CCRCs to ET-1 in both human and rat PRAs (McCullochand MacLean, 1995; McCulloch et al., 1996). In the rat PRAs, thereasons for the biphasic response are still unclear, but it maybe due to a heterogeneous population of ET_B receptors or to thepresence of inhibitory ET_A receptors (McCulloch and MacLean, 1995;McCulloch et al., in press). In human PRAs, the first componentof the response to ET-1 is clearly due to a population of ET_Breceptors mediating vasoconstriction, whereas the second componentis due to higher concentrations of ET-1 causing contraction bystimulating ET_A receptors (McCulloch et al., 1996). In the presentstudy, the shallow component was resistant to the effects of SB209670but sensitive to BQ788. Indeed, the effect of SB209670 was to"uncover" or exaggerate this component. The simplest explanationfor the shallow component of the ET CCRC in the rabbit PRAs isthat there is a heterogeneous population of ET_B-like receptors.However, this interpretation of the data remains speculative.Curve-fitting for a biphasic response is not possible where thefirst component of the curve is less than 30% of the maximal response.This theory cannot therefore be assessed mathematically.

What is clear is that ET_A receptors exert little or no overriding vasoconstrictor influence at any concentration of ET-1.FR139317 did not inhibit responses to ET-1 in either the sham-operatedor the coronary-ligated rabbit vessels. Synergy between ET_A andET_B receptors has, however, been reported in larger rabbit pulmonaryarteries, where administration of both an ET_A and an ET_B receptorinhibitor is required to inhibit responses to ET-1 (Fukuroda etal., 1994b). In the PRAs, however, FR139317 had no effect on theability of BQ788 to inhibit responses to ET-1, which suggeststhat such synergy could not be observed using FR139317 and BQ788as antagonists. The combined effects of FR139317 and BQ788 mightbe expected to be the same as the effect of SB209670. The differentialresults obtained may be explained by SB209670 being considerablymore potent than FR139317 at the ET_A receptor (Ohlstein et al.,1994a; 1994b; Sogabe et al., 1993); this would suggest that ET_Areceptors modulate responses to ET-1. Alternatively, the ET_B receptorpopulation present may be uniquely sensitive to SB209670, or anET_A receptor population in this setting may be sensitive to SB209670but insensitive to FR139317. All these suggestions remain speculative.

We examined the rabbit PRAs for endothelium-dependent vasodilation to determine whether this changed with LVD. Surprisingly,we could find no evidence for endothelium-dependent vasodilation,even though we tried a range of agonists known to induce endothelium-dependentvasodilation in PRAs. Endothelium-dependent relaxation has, however,been demonstrated in adult rabbit large pulmonary arteries (Johnset al., 1989). An absence of endothelium-dependent relaxationcould be due to insensitivity of the vascular smooth muscle toNO, damage to the endothelium or an absence of endothelium-dependentNO. The absence of endothelium-dependent relaxation cannot bedue to insensitivity to NO, because all vessels we tested relaxedin the presence of the NO donor SNP. It is also unlikely thatthe endothelium was damaged by the setting-up procedure, becausewe can demonstrate 100% endothelium-dependent vasodilation infetal and newborn rabbit PRAs, which are considerably more delicatethan the adult vessels (Docherty and MacLean, 1995). We have alsoused agonists other than U46619 to raise the vascular tone andfailed to observe any endothelium-dependent relaxation (C.C. Dochertyand M.R. MacLean, unpublished observations). The most likely explanationfor the absence of endothelium-dependent relaxation is that itdoes not occur in the PRAs from the adult rabbit. These resultsare entirely consistent with previous studies that demonstrateendothelium-dependent vasodilation in large, but not small, pulmonaryarteries of the rat and sheep (Leach et al., 1992; Kemp et al.,1997). The physiological relevance of these observations remainsspeculative. Curiously, however, in the rat, although endothelialNOS (eNOS) activity is normally absent from the endothelium, itcan be observed in PRAs removed from rats with PHT (Isaacson etal., 1994; Xue et al., 1994). In addition, we recently demonstratedan increase in ACh-induced vasodilation in PRAs removed from chronichypoxic PHT rats (MacLean and McCulloch, in press). This mustbe a compensatory event in the face of increased pulmonary pressure.

With regard to the effects of LVD, there was no marked change in the ET receptor profile in terms of agonist sensitivity orantagonist activity. Curiously, however, there was a decreasein the estimated pK_b value for SB209670 against the effect ofS6c in the LVD group. It has been noted previously that SB209670has a similarly reduced pK_b value against S6c in the rabbit bronchuscompared with the rabbit pulmonary artery (Hay et al., 1996).Hay et al. proposed that such differences in antagonist potencycould be explained by differences in the ET_B receptor, differencesin the regional distribution of receptors or differences in theaffinity of the antagonist for different binding domains withina single population of ET_B receptors. Any of these phenomena mayexplain our results, although they are less likely to be explainedby a change in the ET_B receptor itself, because agonist potenciesdo not change and the effect of BQ788 is not altered.

There was a decrease in the maximal response to ET-3 in the vessels removed from the LVD rabbits. The reason is unclear, butit may be related to the possible effect of increased NO production.There was not a general depressant effect, though, because responsesto ET-1 and KCl were not altered. The maximal response to 5-HT,however, was decreased in rabbits with LVD, so some vasoconstrictorssuch as 5-HT and ET-3 may be influenced to a greater extent bychanges in NO activity. The results with KCl show that overallsmooth muscle contractility was not affected by LVD.

The major difference between the sham-operated and LVD rabbits was observed with L-NAME. L-NAME had little effect on responsesto ET-1 and S6c in vessels removed from the sham-operated rabbitsbut markedly potentiated responses in the LVD rabbits. This suggeststhat basal NOS activity was increased in the PRAs removed fromthe LVD rabbits. We have previously shown that there is increasedendogenous tone in pulmonary arteries and arterioles from ratswith PHT and that this may stimulate, and be countered by, endogenousNO release (MacLean et al., 1995; MacLean et al., 1996). Therefore,this phenomenon probably accounts for the increase in basal NOproduction in the PRAs from the rabbits with LVD. These resultsare compatible with the results of other studies that have demonstratedan increase in NO production associated with PHT. For example,there is evidence that NOS may be up-regulated in patients withheart failure, and the inhibition of NOS increased pulmonary vascularresistance in these patients (Habib et al., 1994). This must alsobe a compensatory response to an increase in pulmonary pressure.The results presented here demonstrate that this serves to maintainsensitivity to ET-1 in that the EC₅₀ for ET-1 was the same inthe sham-operated and LVD rabbit vessels. However, if the influenceof NO is removed, this uncovers a 2- to 3-fold increase in sensitivityto ET-1. Hence the increased influence of NO has indeed compensatedfor increased vasoconstrictor influences. It is thought that basaland agonist-stimulated NO activity can be regulated differentially,so it is not surprising that basal NO production can be influenceddespite the absence of agonist-induced release of NO (Mian andMartin, 1995).

The PRAs removed from the rabbits with LVD demonstrated a decreased sensitivity to SNP. In the human, an increase in stimulationby NO by long-term nitrate administration is also followed bya tolerance to the effects of nitrates (Needleman and Johnson,1973). Curiously, we have observed previously that in rats chronicallytreated with L-NAME such that eNOS is depleted, the pulmonaryarteries are hypersensitive to SNP (MacLean and Macmillan, 1993).Hence there is evidence that when there is increased stimulationby NO either by up-regulation of eNOS or by the administrationof nitrates, there is a reduction in sensitivity to NO. When eNOSis inhibited, the reverse case holds, and the smooth muscle becomeshypersensitive to NO.

In conclusion, this study shows that the pharmacology of the ET-1 receptor in rabbit PRAs is complex. There is a vasoconstrictorET_B-like receptor that is BQ788-insensitive but is sensitive toSB209670 and mediates responses to ET-1 with agonist potenciesin the rank order S6c > ET-1 = ET-3. Rabbit PRAs do not demonstrateendothelium-dependent relaxation. An increase in basal NO productionmay be an early physiological compensatory mechanism in responseto the early elevation in pulmonary pressure with LVD to circumventan increase in potency to ET-1.

	Acknowledgments

We wish to acknowledge Dr. M. Hicks, D. Smyllie and colleagues at the Glasgow University Department of Medical Cardiology,Glasgow Royal Infirmary, for preparing the rabbit coronary ligationmodel; and Dr. Ohlstein (SmithKline Beecham Pharmaceuticals) forthe kind donation of SB 209670. We also wish to thank Dr. K.M.McCulloch for her advice in the preparation of this manuscript.C.C. Docherty holds a MRC-funded Ph.D. studentship.

	Footnotes

Accepted for publication November 13, 1997.

Received for publication June 16, 1997.

¹ This work was funded by the Medical Research Council, UK.

Send reprint requests to: Dr. M.R. MacLean, Division of Neuroscience and Biomedical Systems, Institute of Biomedical and Life Sciences, West Medical Building, University of Glasgow, Glasgow, G12 8QQ, Scotland.

	Abbreviations

ET, endothelin; ET-1, endothelin-1; ET-3, endothelin-3; PRA, pulmonary resistance artery; S6c, sarafotoxin S6c; LVD, left ventricular dysfunction; NO, nitric oxide; NOS, nitric oxide synthase, eNOS, endothelial NOS; L-NAME, N-nitro-L-arginine methyl ester; PHT, pulmonary hypertension; CCRC, cumulative concentration response curve; SNP, sodium nitroprusside.

	References

Top Abstract Introduction Materials & Methods Results Discussion References

Arai H, Hori S, Arimori I, Ohkubo H and Nakanishi S (1990) Cloningand expression of a cDNA encoding an endothelin receptor. Nature 348: 730-732[Medline].
Arunlakshana O and Schild HO (1959) Somequantitative uses of antagonists. BrJ Pharmacol Chemother 14: 48-58.[Medline]
Cody RJ, Haas GJ, Binkley PF, Capers Q and Kelley R (1992) Plasmaendothelin correlates with the extent of pulmonary hypertensionin patients with chronic congestive heart failure. Circulation 85: 504-509[Abstract/Free Full Text].
Deuchar GA, Hicks MN, Cobbe SM, Docherty CC and MacLean MR (in press 1998) Pulmonary responses to 5-hydroxytryptamineand endothelin-1 in a rabbit model of left ventricular dysfunction.Cardiovasc Res.
Dochery CC and MacLean MR (1995) Effectof developmental age on noradrenaline- and acetylcholine-evokedresponses in rabbit isolated pulmonary resistance arteries. BrJ Pharmacol 116: 410P.
Douglas SA, Beck GR, Jr, Elliott JD and Ohlstein EH (1995) Pharmacologicevidence for the presence of three functional endothelin receptorsubtypes in the rabbit lateral saphenous vein. BrJ Pharmacol 114: 1529-1540[Medline].
Fukuroda T, Kobayayashi M, Ozaki S, Yano M, Miyauchi T, Onizuka M, Sugishita Y, Goto K and Nishikibe M (1994a) Endothelinreceptor subtypes in human versus rabbit pulmonary arteries. JAppl Physiol 76(5): 1976-1982[Abstract/Free Full Text].
Fukuroda T, Ozaki S, Ihara M, Ishikawa K, Yano M and Nishikibe M (1994b) Synergisticinhibition by BQ-123 and BQ-788 of endothelin-1-induced contractionsof the rabbit pulmonary artery. BrJ Pharmacol 113: 336-338[Medline].
Habib F, Dutka D, Crossman D, Oakley CM and Cleland JGF (1994) Enhancedbasal nitric oxide production in heart failure: Another failedcounter-regulatory vasodilator mechanism? TheLancet 344: 371-373[Medline].
Hay DWP, Luttmann MA, Beck G and Ohlstein EH (1996) Comparisonof endothelin_B (ET_B) receptors in rabbit isolated pulmonary arteryand bronchus. Br J Pharmacol 118: 1209-1217[Medline].
Inoue A, Yanagisawa M, Kimura S, Kasuya Y, Miyauchi T, Goto K and Masaki T (1989) Thehuman endothelin family: Three structurally and pharmacologicallydistinct isopeptides predicted by three separate genes. ProcNatl Acad Sci USA 86: 2863-2867[Abstract/Free Full Text].
Isaacson TC, Hampl V, Weir EK, Nelson DP and Archer SL (1994) Increasedendothelium-derived NO in hypertensive pulmonary circulation ofchronically hypoxic rats. JAppl Physiol 76: 933-940[Abstract/Free Full Text].
Johns RA, Linden JM and Peach MJ (1989) Endothelium-dependentrelaxation and cyclic GMP accumulation in rabbit pulmonary arteryare selectively impaired by moderate hypoxia. CircRes 65: 1508-1515[Abstract/Free Full Text].
Karne S, Jayawirckreme CK and Lerner MR (1993) Cloningand characterisation of an endothelin-3 specific receptor (ETCreceptor) from Xenopus laevis dermal melanophores. JBiochem Res 268: 19126-19133.
Kemp BK, Smolich JJ and Cocks TM (1997) Evidencefor specific regional patterns of responses to different vasoconstrictorsand vasodilators in sheep isolated pulmonary arteries and veins. BrJ Pharmacol 121: 441-450[Medline].
Kiowski W, Sütsch G, Hunziker P, Müller P, Kim J, Oechslin E, Schmitt R, Jones R and Bertel O (1995) Evidencefor endothelin-1-mediated vasoconstriction in severe chronic heartfailure. Lancet 346: 732-736[Medline].
Kloog Y and Sokolovsky M (1989) Similaritiesin the mode and sites of action of sarafotoxin and endothelins. TrendsPharmacol Sci 10: 212-214[Medline].
La Douceur DM, Flynn MA, Keiser JA, Reynolds E and Haleen SJ (1993) ET_Aand ET_B receptors coexist on rabbit pulmonary artery vascularsmooth muscle mediating contraction. BiochemBiophys Res Comm 196(1): 209-215[Medline].
Leach RM, Twort CHM, Meron IRC, Cameron IR and Ward JPT (1992) Acomparison of the pharmacological and mechanical properties invitro of large and small pulmonary arteries of the rat. ClinSci 82: 55-62[Medline].
MacLean MR and Macmillan J (1993) Chronicinhibition of nitric oxide synthase: Effect on endothelium-dependentrelaxation and sensitivity to sodium nitroprusside in rat pulmonaryarteries. Br J Pharmacol 108: 135P.
MacLean MR and McCulloch KM (in press 1998) Influence of applied tension and nitric oxide on responses to endothelinsin rat pulmonary resistance arteries: Effect of chronically hypoxia.Br J Pharmacol.
MacLean MR, McCulloch KM and Baird M (1994) EndothelinET_A and ET_B receptor-mediated vasoconstriction in rat pulmonaryarteries and arterioles. JCardiovasc Pharmacol 23: 838-845[Medline].
MacLean MR, McCulloch KM and Baird M (1995) Effectsof pulmonary hypertension on vasoconstrictor responses to endothelin-1and sarafotoxin S6c and on inherent tone in rat pulmonary arteries. JCardiovasc Pharmacol 26: 822-830[Medline].
MacLean MR, Sweeney G, Baird M, McCulloch KM, Houslay M and Morecroft I (1996) 5-Hydroxytryptaminereceptors mediating vasoconstriction in pulmonary arteries fromcontrol and pulmonary hypertensive rats. BrJ Pharmacol 119: 917-930[Medline].
Masaki T, Kimura S, Yanagisawa M and Goto K (1991) Molecularand cellular mechanisms of endothelin regulation, implicationsfor vascular function. Circulation 84: 1457-1468[Free Full Text].
Masaki T, Yanagisawa M and Goto K (1992) Physiologyand pharmacology of endothelins. MedRes Rev 12: 391-421[Medline].
McCulloch KM, Docherty CC and MacLean MR (in press 1998) Endothelin receptors mediating contraction of rat and humanpulmonary resistance arteries: Effect of chronic hypoxia in therat. Br J Pharmacol.
McCulloch KM, Docherty CC, Morecroft I and MacLean MR (1996) Endothelin_Breceptors mediate contraction of human pulmonary resistance arteries. BrJ Pharmacol 119: 917-930.
McCulloch KM and MacLean MR (1995) Endothelin_Breceptor-mediated contraction of human and rat pulmonary resistancearteries and the effect of pulmonary hypertension on endothelinresponses in the rat. J CardiovascPharmacol 26(3): S169-S176.
Mian KB and Martin W (1995) Differentialsensitivity of basal and acetylcholine-stimulated activity ofnitric oxide to destruction by superoxide anion in rat aorta. BrJ Pharmacol 115: 993-1000[Medline].
Needleman P and Johnson EM (1973) Mechanismof tolerance development to organic nitrates. JPharmacol Exp Ther 184: 709-715[Abstract/Free Full Text].
Ohlstein EH, Beck GR, Jr, Douglas SA, Nambi P, Lago A, Gleason JG, Ruffolo RR, Jr, Feuerstein G and Elliott JD (1994a) Nonpeptideendothelin receptor antagonists. II. Pharmacological characterizationof SB209670. J Pharmacol ExperTher 271: 762-768[Abstract/Free Full Text].
Ohlstein EH, Nambi P, Douglas SA, Edwards RM, Gellai M, Lago A, Leber JD, Cousins RD, Gao A, Frazee JS, Peishoff CE, Bean JW, Eggleston DS, Elshourbagy NA, Kumar C, Lee JA, Yue T, Louden C, Brooks DP, Weinstock J, Feuerstein G, Poste G, Ruffolo RR, Gleason JG and Elliott JD (1994b) SB209670,a rationally designed potent nonpeptide endothelin receptor antagonist. ProcNatl Acad Sci USA 91: 8052-8056[Abstract/Free Full Text].
Pye MP, Black M and Cobbe SM (1996) Comparisonof in-vivo and in-vitro haemodynamic function in experimentalheart failure $---$ use of echocardiography. CardiovascRes 31(6): 873-881[Medline].
Sakai S, Miyauchi T, Sakurai T, Yamaguchi I, Kobayashi G and Sugishita Y (1996) Pulmonaryhypertension caused by congestive heart failure is amelioratedby long-term application of an endothelin receptor antagonist. JAm Coll Cardiol 28: 1580-1588[Abstract].
Sakurai T, Yanagisawa M, Takuwa Y, Miyazaki H, Kimura S, Goto K and Masaki T (1990) Cloningof a cDNA encoding a non-isopeptide-selective subtype of the endothelinreceptor. Nature 348: 732-735[Medline].
Sogabe K, Nirel H, Shouba M, Nomoto A, Ao S, Notsu Y and Ono T (1993) Pharmacologicalprofile of FR 139317, a novel, potent, endothelin ETA receptorantagonist. J Pharmacol ExpTher 264: 1040-1046[Abstract/Free Full Text].
Sokolofsky M, Ambar I and Galron R (1992) Anovel subtype of endothelin receptors. JBiol Chem 267: 20551-20554[Abstract/Free Full Text].
Stewart DJ, Levy RD, Cernacek P and Langleben D (1991) Increasedplasma endothelin-1 in pulmonary hypertension: Marker or mediatorof disease? Ann Intern Med 114: 464-469.
Warner TD, Allcock GH, Corder R and Vane JR (1993) Useof endothelin antagonists BQ-123 and PD 142893 to reveal threeendothelin receptors mediating smooth muscle contraction and releaseof EDRF. Br J Pharmacol 110: 777-782[Medline].
Xue C, Rengasamy A, LeCras TD, Koberna PA, Dailey GC and Johns RA (1994) Distributionof NOS in normoxic vs. hypoxic rat lung: Up-regulation of NOSby chronic hypoxia. Am J Physiol 267: L667-L678[Abstract/Free Full Text].
Yoshibayashi M, Nishioka K, Nakao K, Saito Y, Matsumura M, Ueda T, Temma S, Shirakami G, Imura H and Mikawa H (1991) Plasmaendothelin concentration in patients with pulmonary hypertensionassociated with congenital heart defects. Evidence for increasedproduction of endothelin in the pulmonary circulation. Circulation 84: 2280-2285[Abstract/Free Full Text].

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EndothelinB Receptors in Rabbit Pulmonary Resistance Arteries: Effect of Left Ventricular Dysfunction1

Endothelin_B Receptors in Rabbit Pulmonary Resistance Arteries: Effect of Left Ventricular Dysfunction¹