ETA and ETB receptors on single smooth muscle cells cooperate in mediating guinea pig tracheal contraction

Gq/G13signaling by ET-1 in smooth muscle: MYPT1 phosphorylation via ETAand CPI-17 dephosphorylation via ETB

We analyzed the signaling pathways initiated by endothelin receptors ETAand ETBin intestinal circular and longitudinal smooth muscle cells. The response to endothelin-1 (ET-1) consisted of two phases in both cell types. The initial, transient phase of contraction and phosphorylation of 20-kDa myosin light chain (MLC20) was mediated additively by ETAand ETBreceptors and initiated by Gαq-, Ca2+/calmodulin-dependent activation of MLC kinase. In contrast, the sustained phase was mediated selectively by ETAreceptors via a pathway involving sequential activation of Gα13, RhoA, and Rho kinase, resulting in phosphorylation of MYPT1 at Thr696and phosphorylation of MLC20. Although PKC was activated, CPI-17 was not phosphorylated and hence did not contribute to inhibition of MLC phosphatase. The absence of CPI-17 phosphorylation by PKC reflected active dephosphorylation of CPI-17 by protein phosphatase 2A (PP2A). PP2A was activated via a pathway involving ETB-dependent stimulation of p38 MAPK activity. CPI-17 phosphorylation was unmasked in the presence of the ETBantagonist BQ-788, but not the ETAantagonist BQ-123, and in the presence of a low concentration of okadaic acid, which selectively inactivates PP2A. The resultant phosphorylation of CPI-17 was blocked by bisindolylmaleimide, providing direct confirmation that it was PKC dependent. We conclude that the two phases of the intestinal smooth muscle response to ET-1 involve distinct receptors, G proteins, and signaling pathways. The sustained response is mediated via selective ETA-dependent phosphorylation of MYPT1. In contrast, ETBinitiates an inhibitory pathway involving p38 MAPK-dependent activation of PP2A that causes dephosphorylation of CPI-17.

Specific detection of the endogenous transient receptor potential (TRP)-1 protein in liver and airway smooth muscle cells using immunoprecipitation and Western-blot analysis

Although there are numerous reports of the presence of mRNA encoding the transient receptor potential (TRP)-1 protein in animal cells and of the detection of the heterologously expressed TRP-1 protein by Western-blot analysis, it has proved difficult to unequivocally detect endogenous TRP-1 proteins. A combination of immunoprecipitation and Western-blot techniques, employing a polyclonal antibody and a monoclonal antibody respectively, was developed. Using this technique, a band of approx. 80 kDa was detected in extracts of H4-IIE rat liver hepatoma cell line and guinea-pig airway smooth muscle (ASM) cells transfected with human TRPC-1 cDNA. In extracts of untransfected H4-IIE cells, ASM cells, rat brain and guinea-pig brain, a band of approx. 92 kDa was detected. Reverse transcriptase PCR experiments detected cDNA encoding both the alpha- and beta-isoforms of TRP-1 in H4-IIE cells. Treatment of protein extracts with peptide N-glycosidase F indicated that the 92 kDa band represents an N-glycosylated protein. Western blots conducted with a commercial polyclonal anti-(TRP-1) antibody (Alm) detected a band of 120 kDa in extracts of H4-IIE cells and guinea-pig ASM cells. A combination of immunoprecipitation and Western-blotting techniques with the Alm antibody did not detect any bands at 92 kDa or 120 kDa in extracts of H4-IIE and ASM cells. It is concluded that (a) the 92-kDa band detected in untransfected H4-IIE and ASM cells corresponds to the N-glycosylated beta-isoform of endogenous TRP-1, (b) the combined immunoprecipitation and Western-blot approach, employing two different antibodies, provides a reliable and specific procedure for detecting endogenous TRP-1 proteins, and (c) that caution is required in developing and utilizing anti-(TRP-1) antibodies.

Prostaglandin E(2) increases cyclic AMP and inhibits endothelin-1 production/secretion by guinea-pig tracheal epithelial cells through EP(4) receptors

Prostaglandin E(2) (PGE(2)) increased adenosine 3' : 5'-cyclic monophosphate (cyclic AMP) formation in tracheal epithelial cells and concomitantly decreased the production/secretion of immunoreactive endothelin (irET). Naturally occurring prostanoids and selective and non-selective EP receptor agonists showed the following rank order of potency in stimulating cyclic AMP generation by epithelial cells: PGE(2) (EP-selective)>16,16-dimethyl PGE(2) (EP-selective)>11-deoxy PGE(2) (EP-selective)>>>iloprost (IP/EP(1)/EP(3)-selective), butaprost (EP(2)-selective), PGD(2) (DP-selective), PGF(2alpha) (FP-selective). The lack of responsiveness of the latter prostanoids indicated that the prostanoid receptor present in these cells is not of the DP, FP, IP, EP(1), EP(2) or EP(3) subtype. Pre-incubating the cells with the selective TP/EP(4)-receptor antagonists AH23848B and AH22921X antagonized the PGE(2)-evoked cyclic AMP generation. This suggested that EP(4) receptors mediate PGE(2) effects. However, in addition to any antagonistic effects at EP(4)-receptors, both compounds, to a different extent, modified cyclic AMP metabolism. The selective EP(1), DP and EP(2) receptor antagonist (AH6809) failed to inhibit PGE(2)-evoked cyclic AMP generation which confirmed that the EP(2) receptor subtype did not contribute to the change in cyclic AMP formation in these cells. The PGE(2)-induced inhibition of irET production by guinea-pig tracheal epithelial cells was due to cyclic AMP generation and activation of the cyclic AMP-dependent protein kinase since this effect was reverted by the cyclic AMP antagonist Rp-cAMPS. These results provide the first evidence supporting the existence of a functional prostaglandin E(2) receptor that shares the pharmacological features of the EP(4)-receptor subtype in guinea-pig tracheal epithelial cells. These receptors modulate cyclic AMP formation as well as ET-1 production/secretion in these cells.

Adenosine induces cyclic-AMP formation and inhibits endothelin-1 production/secretion in guinea-pig tracheal epithelial cells through A(2B) adenosine receptors

1. The adenosine receptor subtype mediating adenosine 3' : 5'-cyclic monophosphate (cyclic AMP) formation and the effect of its activation on endothelin-1 (ET-1) secretion were studied in primary cultures of tracheal epithelial cells. 2. Adenosine analogues showed the following rank order of potency (pD(2) value) and intrinsic activity on the generation of cyclic AMP by tracheal epithelial cells: 5'-N-ethylcarboxyamidoadenosine (NECA, A(1)/A(2A)/A(2B), pD(2): 5.44+/-0.16)>adenosine (ADO, non selective, pD(2): 4.99+/-0. 09; 71+/-9% of NECA response) >/=2-Cl-adenosine (2CADO, non selective, pD(2): 4.72+/-0.14; 65+/-9% of NECA response)>>>CGS21680 (A(2A); inactive at up to 100 microM). 3. Cyclic AMP formation stimulated by NECA in guinea-pig tracheal epithelial cells was inhibited by adenosine receptor antagonist with the following order of apparent affinity (pA(2) value): Xanthine amine congeners (XAC, A(2A)/A(2B), 7.89+/-0.22)>CGS15943 (A(2A)/A(2B), 7.24+/-0. 26)>ZM241385 (A(2A), 6.69+/-0.14)>DPCPX (A(1), 6.51+/-0. 14)>3n-propylxanthine (weak A(2B), 4.30+/-0.10). This rank order of potency is typical for A(2B)-adenosine receptor. 4. Adenosine decreased basal and LPS-stimulated irET production in a concentration-dependent manner. Moreover, NECA but not CGS21680 inhibited LPS-induced irET production. 5. The inhibitory effect of NECA on LPS-induced irET production was reversed by XAC (pA(2)=8.84+/-0. 12) and DPCPX (pA(2)=8.10+/-0.22). 6. These results suggested that adenosine increased cyclic AMP formation and inhibited irET production/secretion by guinea-pig tracheal epithelial cells through the activation of a functional adenosine receptor that is most likely the A(2B) subtype. This adenosine receptor may be involved in the regulation of the level of ET-1 production/secretion by guinea-pig tracheal epithelial cells in physiological as well as in pathophysiological conditions.

Selective activation of excitation-contraction coupling pathways by ET(A) and ET(B) receptors in guinea-pig tracheal smooth muscle

1. Signalling events responsible for endothelin(A) (ET(A)) and ET(B) receptor-induced contraction were examined in epithelium-denuded guinea-pig tracheal smooth muscle strips. Selective stimulation of each subtype was achieved by a combination of ET-1 (100 nM) and ET(A) and ET(B) receptor-selective antagonists, BQ-123 (10 microM) and BQ-788 (3 microM), respectively. 2. Both ET(A) and ET(B) receptors induced long-lasting contraction that was totally dependent on Ca2+ influx. Stimulation of ET(A) receptor induced both transient and sustained (Ca2+)i increases whereas that of ET(B) receptor induced only a sustained increase. Suppression of the transient (Ca2+)i increase by U73122 (3 microM) did not affect the ET(A)-induced sustained (Ca2+)i increase and tension development. Stimulation of ET(A) receptor, but not ET(B), induced phosphoinositide breakdown and protein kinase C (PKC). The activated PKC contributed to the contraction by increasing the Ca2+ sensitivity of the contractile apparatus. 3. Thus, ET(A) receptor is coupled both with phospholipase C/Ca2+/PKC signalling and Ca2+ influx pathways whereas ET(B) receptor was coupled only with the latter. 4. Stimulation of ET(B) receptor, but not ET(A), caused membrane depolarization measured with a fluorescent indicator, bis-(1,3 dibutylbarbituric acid)-trimethine oxonol. Both nifedipine (1 microM) and verapamil (10 microM) abolished ET(B)-induced Ca2+ influx and contraction, while they barely affected ET(A)-induced responses. 5. Therefore, the Ca2+ influx pathways activated by each subtype appeared to be completely different; ET(A) and ET(B) receptors opens voltage-independent Ca2+ channels and L-type voltage-dependent Ca2+ channels, respectively.

Influence of respiratory tract viral infection on endothelin-1-induced potentiation of cholinergic nerve-mediated contraction in mouse trachea

1. This study examined the influence of respiratory tract infection with influenza A/PR-8/34 virus on endothelin receptor-mediated modulation of contraction induced by stimulation of cholinergic nerves in mouse isolated trachea. 2. The ETB receptor-selective agonist, sarafotoxin S6c (30 nM) induced large transient contractions (118 +/- 5% Cmax, n = 13; where Cmax is the contraction induced by 10 microM carbachol) of isolated tracheal segments from control mice. The peak contractile response to 30 nM sarafotoxin S6c was significantly lower in preparations from virus-inoculated mice at day 2 (57 +/- 8% Cmax, n = 3, P < 0.05) and 4 post-inoculation (90 +/- 8% Cmax, n = 9, P < 0.05), consistent with virus-induced attentuation of the ETB receptor-effector system linked to airway smooth muscle contraction. The mean peak contraction to 30 nM sarafotoxin S6c of preparations from virus-inoculated mice at day 8 post-inoculation (94 +/- 17% Cmax, n = 4) was not significantly different from that of control. 3. Electrical field stimulation (EFS; 90 V, 0.5 ms duration, 10 s train, 0.1-30 Hz) of preparations from control and virus-inoculated mice, caused contractions that were abolished by 0.1 microM atropine or 3 microM tetrodotoxin, indicating that these responses were mediated by neuronally released acetylcholine. Sarafotoxin S6c markedly potentiated contractions induced by a standard stimulus (0.3 Hz, every 3 min) in tracheal segments from control and virus-inoculated mice. In tracheal tissue from control mice, 30 nM sarafotoxin S6c significantly increased a standard EFS-induced contraction of 24 +/- 4% Cmax by a further 24 +/- 3% Cmax (i.e. 2 fold increase, n = 11). Sarafotoxin S6c (30 nM) also markedly potentiated standard EFS-induced contractions in preparations from virus-inoculated mice at day 2 (17 +/- 2% Cmax, n = 3), day 4 (17 +/- 5% Cmax, n = 9) and day 8 (26 +/- 5% Cmax, n = 4) post-inoculation. The level of potentiation of EFS-induced contractions in preparations from virus-inoculated mice was similar to that in tissue from control mice at days, 2, 4 and 8 post-inoculation. In contrast, sarafotoxin S6c (30 nM) did not enhance contractile responses of tracheal segments from control and virus-inoculated mice to exogenously applied acetylcholine (n = 3). 4. Endothelin-1 (1 nM) caused similar potentiations of standard EFS-induced contractions in tracheal segments from control (13 +/- 2% Cmax, n = 23) and virus-inoculated mice at day 2 (13 +/- 1% Cmax, n = 5), day 4 (16 +/- 5% Cmax, n = 6), and day 8 (13 +/- 3% Cmax, n = 8) post-inoculation. In contrast, 1 nM endothelin-1 did not enhance contractile responses of tracheal segments from control and virus-inoculated mice to exogenously applied acetylcholine (n = 4). Neither the ETA receptor-selective antagonist, BQ-123 (3 microM) nor the ETB receptor-selective antagonist, BQ-788 (1 microM) alone had any significant inhibitory effect on endothelin-1-induced potentiations of tracheal segments from control or virus-inoculated mice at days 2, 4 and 8 post-inoculation. However, simultaneous pre-incubation with BQ-123 (3 microM) and BQ-788 (1 microM) prevented endothelin-1-evoked potentiations, indicative of a role for both ETA and ETB receptors in this system. 5. These data clearly demonstrate that respiratory tract viral infection attenuated the function of the postjunctional ETB receptor-effector system linked directly to airway smooth muscle contraction. However, the function of prejunctional ETA and ETB receptor-effector systems linked to augmentation of cholinergic nerve-mediated airway smooth muscle contraction remained unaffected during respiratory tract viral infection in mice.

The induction of a biphasic bronchospasm by the ETB agonist, IRL 1620, due to thromboxane A2 generation and endothelin-1 release in guinea-pigs

1. IRL 1620 (0.01-0.1 mg kg-1, i.v.), a selective endothelin B (ETB) receptor agonist, induced a dose-dependent biphasic increase in total lung resistance and a decrease in dynamic compliance in anaesthetized and artificially ventilated guinea-pigs. After intravenous injection of IRL 1620 (0.03 mg kg-1), the first phase was observed within 2 min whereas the second phase started between 5 and 10 min after injection and was long lasting. 2. In order to characterize which endothelin receptors are involved in both phases of bronchoconstriction, we studied the effect of ETA and ETB receptor antagonists (BQ 123 and BQ 788, respectively). BQ 788 (0.1-1 mg kg-1, i.v.) inhibited, in a dose-dependent manner, both phases of bronchoconstriction. BQ 123 (3 mg kg-1, i.v.) markedly inhibited (by 76%) the second phase of bronchoconstriction but had no effect on the early component of the response. 3. The effect of atropine, neurokinin-I (NK1) and neurokinin-2 (NK2) receptor antagonists (SR140333 and SR48968, respectively) were tested to investigate the possible involvement of cholinergic and sensory nerve activation, respectively, in the response to IRL 1620. Likewise, the role of arachidonic acid metabolites (leukotriene D4 antagonist, ONO-1078 and thromboxane A2 (TXA2) inhibitor, OKY-046) in this response was also investigated. OKY-046 (1 mg kg-1, i.v.) and atropine (1 mg kg-1, i.v.) partially inhibited the first phase (by 80% and 20%, respectively) without affecting the late phase of bronchoconstriction. Neither ONO-1078 (1 mg kg-1, i.v.) nor the combination of SR140333 (0.2 mg kg-1, i.v.) and SR 48968 (0.2 mg kg-1, i.v.) modified IRL 1620-induced bronchoconstriction. 4. A low dose of IRL 1620 (0.005 mg kg-1, i.v.) induced a monophasic bronchoconstriction. Pretreatment by phosphoramidon (100 mumol kg-1, i.v.) restored the second phase of bronchoconstriction. In this condition, BQ 123 (3 mg kg-1, i.v.) was able to inhibit partially the second phase of bronchoconstriction. 5. These results suggest that both phases of bronchoconstriction induced by IRL 1620 were mediated primarily by ETB receptor activation, the first phase being a consequence of TXA2 and acetylcholine release. The inhibition by an ETA receptor antagonist and the restoration by a neutral endopeptidase (NEP) inhibitor of the second phase of bronchoconstriction suggests that primary activation of ETB receptors leads to autocrine/paracrine endothelin-1 (ET-1) release that would subsequently cause profound bronchoconstriction through both ETA and ETB receptor activation.

Endothelins-induce cyclicAMP formation in the guinea-pig trachea through an ETA receptor- and cyclooxygenase-dependent mechanism

1. The non-selective endothelin agonist, endothelin-1 (ET-1), and the selective ETB receptor agonist, sarafotoxin-S6c (SRTX-c), contracted guinea-pig isolated trachea in a concentration-dependent manner. The EC50 value for ET-1 (11 +/- 2.1 nM) was significantly higher than that of SRTX-c (3.2 +/- 0.21 nM) and the maximal developed tension due to SRTX-c was 42.8 +/- 2.3% higher than that produced by ET-1 (P < 0.05). 2. Pretreatment with the ETA antagonist, BQ-610, appreciably enhanced the developed tension due to ET-1 but not SRTX-c. Likewise, the cyclo-oxygenase inhibitor, indomethacin, markedly potentiated the contractile responses to ET-1, but not to SRTX-c. Combining BQ-610 with indomethacin was not more effective than either of them in augmenting ET-1-evoked tension. 3. ET-1 significantly increased cyclic AMP formation in the trachea in concentration- and time-dependent manners. A t1/2 value of 4.3 min, an EC50 value of 20 +/- 3 nM and a maximal cyclic AMP increment of 124% above the basal level, were obtained for ET-1. Similarly but less effectively, ET-3 (0.1 microM) increased cyclic AMP level (35 +/- 3.7% compared to 94 +/- 7.8% for the same concentration of ET-1). By contrast, SRTX-c did not alter the cyclicAMP level when applied in concentrations up to 1 microM. 4. Pre-incubation of the trachea with BQ-610 (1 microM) or indomethacin (1 microM) prevented cyclicAMP formation by either ET-1 or ET-3. 5. The results of the present study indicate a negative regulatory role mediated by the ETA receptor on the ETB-triggered mechanical response. This effect is likely to be mediated by activation of adenylate cyclase through a cyclo-oxygenase-dependent mechanism.

Time course of changes in ETB receptor density and function in tracheal airway smooth muscle during respiratory tract viral infection in mice

1. In the current study, the density and function of ETA and ETB receptors in mouse tracheal airway smooth muscle were determined over the time course of respiratory tract infection with influenza A/PR-8/34 virus. 2. Quantitative autoradiographic studies using [125I]-endothelin-1 revealed that the tracheal airway smooth muscle from control mice contained ETA and ETB sites in the ratio of 49%:51% (+/- 2%, n = 29 mice). Respiratory tract viral infection was associated with increases in the density of ETA sites and decreases in the density of ETB sites at days 1, 2 and 4 post-inoculation which were reversible by day 19. For example, at day 4 post-inoculation, a time when the manifestations of viral infection were at or near their peak, the ratio of ETA:ETB sites was 72%:28% (+/- 4%, n = 6 mice, P < 0.05). In contrast, at day 19 post-inoculation, by which time viral infection had essentially resolved, the ratio of ETA:ETB sites was similar to control (51%:49% (+/- 3%), n = 6 mice). 3. Endothelin-1 was a potent spasmogen in isolated tracheal airway smooth muscle preparations from control mice (ED70 = concentration producing 70% of contraction induced by 10 microM carbachol = 6.3 nM (95% confidence limits, 4.0-10; n = 6 mice)). Neither the ETA receptor-selective antagonist, BQ-123 (3 microM), nor the ETB receptor-selective antagonist, BQ-788 (1 microM) alone had any significant inhibitory effect on endothelin-1-induced contractions of mouse isolated tracheal smooth muscle. However, simultaneous treatment with BQ-123 (3 microM) and BQ-788 (1 microM) resulted in a 10 fold rightward shift in the concentration-effect curve to endothelin-1 (ED70 = 60 nM, (44-90; n = 6 mice, P < 0.05)), indicating that contraction was mediated via both ETA and ETB receptors. 4. Endothelin-1 evoked similar concentration-dependent contractions of tracheal smooth muscle isolated from control and virus-inoculated mice. In the presence of the ETB receptor-selective-antagonist, BQ-788 (1 microM), the potency and maximum response to endothelin-1 were similar in preparations from control and virus-inoculated mice at all time points investigated. However, unlike control responses, endothelin-1-induced contractions in preparations from virus-infected mice were significantly inhibited by the ETA receptor-selective antagonist, BQ-123. For example, at day 4 post-inoculation, the contractile response to 30 nM endothelin-1, in the presence of BQ-123 (3 microM), was only 20 +/- 12% (n = 6 mice, P < 0.05) of that produced in control preparations under similar conditions. However, at day 19 post-inoculation, contraction evoked by 30 nM endothelin-1 in the presence of BQ-123 (3 microM), was similar to that in preparations from control mice. 5. In summary, during the early stages (days 1-8 post-inoculation) of respiratory tract infection with influenza A/PR-8/34 virus, we observed decreases in the density of tracheal airway smooth muscle ETB receptors which were reflected in decreases in ETB receptor-mediated airway smooth muscle contraction. In addition, during the same period of viral infection we observed increases in the density of tracheal airway smooth muscle ETA receptors which were not associated with increased function of the ETA receptor-effector system linked to contraction. Virus-associated modulation of ETA and ETB receptor density and function was reversible with recovery from infection.

Influence of regional differences in ETA and ETB receptor subtype proportions on endothelin-1-induced contractions in porcine isolated trachea and bronchus

1. Quantitative autoradiographic studies were conducted to determine the distributions and densities of ETA and ETB binding site subtypes in porcine tracheal and bronchial smooth muscle. In addition, the roles of ETA and ETB receptors in endothelin-1-mediated contraction of these tissues were assessed. 2. Quantitative autoradiographic studies revealed that both ETA and ETB binding sites for [125I]-endothelin-1 were present in both bronchial and tracheal airway smooth muscle. However, the proportions of these sites were markedly different at these two levels within the respiratory tract. In tracheal smooth muscle, the proportions of ETA and ETB sites were 30 +/- 1% and 70 +/- 1% respectively, whereas in bronchial smooth muscle, these proportions were virtually reversed, being 73 +/- 2% and 32 +/- 8% respectively. 3. Endothelin-1 induced concentration-dependent contraction of porcine tracheal and bronchial airway smooth muscle. Endothelin-1 had similar potency (concentration producing 30% of the maximum carbachol contraction, Cmax) in trachea (22 nM; 95% confidence limits (c.l.), 9-55 nM; n = 9) and bronchus (22 nM; c.l., 9-55 nM; n = 6). Endothelin-1 also produced comparable maximal contractions in trachea (59 +/- 5% Cmax; n = 9) and bronchus (65 +/- 4% Cmax, n = 6). 4. In trachea, endothelin-1 induced contractions were not significantly inhibited by either the ETA receptor-selective antagonist, BQ-123 (3 microM) or the ETB receptor-selective antagonist, BQ-788 (1 microM). However, in the combined presence of BQ-123 and BQ-788, the concentration-effect curve to endothelin-1 was shifted to the right by 3.7 fold (n = 8; P = 0.01). 5. In bronchus, concentration-effect curves to endothelin-1 were shifted to the right by BQ-123 (3 microM; 4.3 fold; P < 0.05), but not by BQ-788 (1 microM). In the presence of both antagonists, concentration-effect curves to endothelin-1 were shifted by at least 6.7 fold (n = 6; P = 0.01). 6. Sarafotoxin S6c induced contraction in both tissue types, although the maximum contraction was greater in trachea (53 +/- 7% Cmax; n = 6) than in bronchus (21 +/- 5% Cmax; n = 6). BQ-788 (1 microM) markedly reduced sarafotoxin S6c potency in both trachea and bronchus (e.g. by 50 fold in trachea; c.l., 14-180; n = 6; P < 0.05). 7. These data demonstrate that the proportions of functional endothelin receptor subtypes mediating contraction of airway smooth muscle to endothelin-1, vary significantly at different levels in the porcine respiratory tract.

Role of the neutral endopeptidase 24.11 in the conversion of big endothelins in guinea-pig lung parenchyma

1. We have studied the conversion of big endothelin-1 (big ET-1), big endothelin-2 (big ET-2) and big endothelin-3 (big ET-3) and characterized the enzyme involved in the conversion of the three peptides in guinea-pig lung parenchyma (GPLP). 2. Endothelin-1 (ET-1), endothelin-2 (ET-2) and endothelin-3 (ET-3) (10 nM to 100 nM) caused similar concentration-dependent contractions of strips of GPLP. 3. Big ET-1 and big ET-2 also elicited concentration-dependent contractions of GPLP strips. In contrast, big ET-3, up to a concentration of 100 nM, failed to induce a contraction of the GPLP. 4. Incubation of strips of GPLP with the dual endothelin converting enzyme (ECE) and neutral endopeptidase (NEP) inhibitor, phosphoramidon (10 microM), as well as two other NEP inhibitors thiorphan (10 microM) or SQ 28,603 (10 microM) decreased by 43% (P < 0.05), 42% (P < 0.05) and 40% (P < 0.05) the contractions induced by 30 nM of big ET-1 respectively. Captopril (10 microM), an angiotensin-converting enzyme inhibitor, had no effect on the contractions induced by big ET-1. 5. The incubation of strips of GPLP with phosphoramidon (10 microM), thiorphan (10 microM) or SQ 28,603 (10 microM) also decreased by 74% (P < 0.05), 34% and 50% (P < 0.05) the contractions induced by 30 nM big ET-2 respectively. As for the contractions induced by big ET-1, captopril (10 microM) had no effect on the concentration-dependent contractions induced by big ET-2. 6. Phosphoramidon (10 microM), thiorphan (10 microM) and SQ 28,603 (10 microM) significantly potentiated the contractions of strips of GPLP induced by both ET-1 (30 nM) and ET-3 (30 nM). However, the enzymatic inhibitors did not significantly affect the contractions induced by ET-2 (30 nM) in this tissue. 7. These results suggest that the effects of big ET-1 and big ET-2 result from the conversion to ET-1 and ET-2 by at least one enzyme sensitive to phosphoramidon, thiorphan and SQ 28,603. This enzyme corresponds possibly to EC 3.4.24.11 (NEP 24.11) and could also be responsible for the degradation of ETs in the GPLP.