Inhibition of platelet aggregation ex vivo is repressed in apolipoprotein E deficient mice.

In the present study, we assessed whether the endogenous platelet inhibitory mechanisms are altered in the early to moderate stages of the atherosclerotic process. Apolipoprotein E deficient mice (ApoE-/-), a mouse model of atherosclerosis, and their wild-type (WT) counterparts were used to assess agonist-stimulated synthesis of prostacyclin (PGI2), inhibition of platelet aggregation ex vivo, and intra-platelet cAMP levels. Basal U46619 and ADP -induced platelet aggregation in vitro were increased in ApoE-/- mice at 18-20 weeks in comparison with 8-10 weeks of age. Systemically administered endothelin-1 (ET-1) or bradykinin (BK) inhibited platelet aggregation in a similar fashion in 8- to 10-week-old ApoE-/- and WT mice, but not in the ApoE-/- mice at 18-20 weeks of age, although both peptides maintained their capacity to increase plasma levels of the PGI2. Intravenous infusion of PGI2 also failed to inhibit platelet aggregation ex vivo in 18- to 20-week-old ApoE-/- mice. Interestingly, both BK and PGI2 retained their ability to increase intraplatelet cAMP in WT and ApoE-/- mice. Our results suggest that a loss of activity of endogenous inhibitorymechanisms could contribute to the increased platelet reactivity in ApoE-/- mice, and that this phenomenon occurs early in the intermediate stage of the atherosclerotic process.

Chronic ethanol intake modulates vascular levels of endothelin-1 receptor and enhances the pressor response to endothelin-1 in anaesthetized rats.

BACKGROUND AND PURPOSE: The contribution of endothelin-1 (ET-1) to vascular hyper-reactivity associated with chronic ethanol intake, a major risk factor in several cardiovascular diseases, remains to be investigated. EXPERIMENTAL APPROACH: The biphasic haemodynamic responses to ET-1 (0.01-0.1 nmol kg(-1), i.v.) or to the selective ETB agonist, IRL1620 (0.001-1.0 nmol kg(-1), i.v.), with or without ETA or ETB antagonists (BQ123 (c(DTrp-Dasp-Pro-Dval-Leu)) at 1 and 2.5 mg kg(-1) and BQ788 (N-cis-2,6-dimethyl-piperidinocarbonyl-L-gamma-methylleucyl1-D-1methoxycarbonyltryptophanyl-D-norleucine) at 0.25 mg kg(-1), respectively) were tested in anaesthetized rats, after 2 weeks' chronic ethanol treatment. Hepatic parameters and ET receptor protein levels were also determined. KEY RESULTS: The initial hypotensive responses to ET-1 or IRL1620 were unaffected by chronic ethanol intake, whereas the subsequent pressor effects induced by ET-1, but not by IRL1620, were potentiated. BQ123 at 2.5 but not 1 mg kg(-1) reduced the pressor responses to ET-1 in ethanol-treated rats. Conversely, BQ788 (0.25 mg kg(-1)) potentiated ET-1-induced increases in mean arterial blood pressure in control as well as in ethanol-treated rats. Interestingly, in the latter group, increases in heart rate, induced by ET-1 at a dose of 0.025 mg kg(-1) were enhanced following ETB receptor blockade. Finally, we observed higher levels of ETA receptor in the heart and mesenteric artery and a reduction of ETB receptor protein levels in the aorta and kidney from rats chronically treated with ethanol. CONCLUSIONS AND IMPLICATIONS: Increased vascular reactivity to ET-1 and altered protein levels of ETA and ETB receptors could play a role in the pathogenesis of cardiovascular complications associated with chronic ethanol consumption.

Endothelin-1 (1-31): from chymase-dependent synthesis to cardiovascular pathologies.

The mast cell-derived serine protease chymase is importantly involved not only in degradation, but in synthesis of bioactive peptides as well. Several studies suggest that chymase is the predominant enzyme in the production of angiotensin II (Ang II) from angiotensin-I in interstitial tissues. Interestingly, chymase has also been suggested to mature endothelin-1 (ET-1) from its precursor, big-ET-1 in vitro. The lack of availability of specific chymase inhibitors, beyond the chymotrypsin-like inhibitor chymostatin, currently hampers the investigation of the chymase/ET-1/Ang II paradigm in physiology and cardiovascular diseases. Nonetheless, the recent advent of highly selective chymase inhibitors is shedding new light on the role of this enzymatic pathway in the several inflammatory prone vascular diseases as summarized in the present review. Considering increasing evidence towards significant interactions between Ang II and ET-1 in cardiovascular diseases, the present review will address the role of chymase in the production of those two peptides. Whether chymase-dependent production of ET-1 plays an important role in cardiovascular pathologies will also be discussed.

Characterization of the non-adrenergic/non-cholinergic response to perivascular nerve stimulation in the double-perfused mesenteric bed of the mouse.

BACKGROUND AND PURPOSE: Calcitonin gene-related peptide (CGRP), a capsaicin-sensitive neuromodulator of splanchnic vascular tone in several animal species, remains poorly investigated in mouse models. We therefore assessed whether endogenous CGRP is a non-adrenergic/non-cholinergic (NANC) neuromodulator in the mesenteric vascular bed of the mouse. EXPERIMENTAL APPROACH: Arterial and venous changes in perfusion pressure in response to perivascular nerve stimulation (PNS) were monitored in the mouse mesenteric bed under basal conditions or precontracted with KCl (artery) or U46619 (vein) in circuits pretreated with guanethidine, atropine, indomethacin and prazosin. Arterial responses to NANC were also characterized with a CGRP1 antagonist, halphaCGRP8-37. Finally, the PNS-induced release of arterial CGRP was measured by enzyme immunoassay. KEY RESULTS: HalphaCGRP8-37 enhanced PNS-induced arterial increases in perfusion pressure under basal tone. PNS-induced stimulation of NANC triggered an halphaCGRP8-37 or capsaicin- sensitive reduction in perfusion pressure of the pre-contracted arterial bed only. Chemical removal of the endothelium inhibited PNS- and halphaCGRP- induced reduction in perfusion pressure in the arterial mesenteric bed. Responses to NANC nerves were reduced by guanylate and adenylate cyclase inhibitors (1H-[1,2,4]oxadiazole[4,3-a] quinoxalin-1-one (ODQ)) and [9-(tetrahydro-2-furanyl)-9H-purin-6-amine] (SQ 22,536), respectively. A neuronal NOS inhibitor (7-nitroindazole; 7-NI) also enhanced the response to NANC in vessels from wild-type, eNOS KO but not iNOS KO mice. Finally, PNS enhanced the release of immunoreactive CGRP from the perfused arterial mesenteric bed. CONCLUSIONS AND IMPLICATIONS: Our study demonstrates a role for CGRP in the NANC-dependent reduction in perfusion pressure of the arterial but not venous mesenteric bed of the mouse.

Endothelin-1: Biosynthesis, Signaling and Vasoreactivity.

Endothelin-1 (ET-1) is an extremely potent vasoconstrictor peptide originally isolated from endothelial cells. Its synthesis, mainly regulated at the gene transcription level, involves processing of a precursor by a furin-type proprotein convertase to an inactive intermediate, big ET-1. The latter peptide can then be cleaved directly by an endothelin-converting enzyme (ECE) into ET-1 or reach the active metabolite through a two-step process involving chymase hydrolyzing big ET-1 to ET-1 (1-31), itself needing conversion to ET-1 by neprilysin (NEP) to exert physiological activity. ET-1 signals through two G protein-coupled receptors, endothelin receptor A (ETA) and endothelin receptor B (ETB). Both receptors induce an increase in intracellular Ca(2+), mainly from the extracellular space through voltage-independent mechanisms, the receptor-operated channels and store-operated channels. ET-1 also induces signaling through epidermal growth factor receptor transactivation, oxidative stress induction, rho-kinase, and the activation (ETA) or inhibition (ETB) of the adenylate cyclase/cyclic adenosine monophosphate pathway. Arterial vasoconstriction is mediated mainly by the ETA receptor. ET-1, via endothelium-located ETB, relaxes arteries or constricts vessels following activation of the same receptor type on the smooth muscle, where it can interact with ETA. In addition, ETB-dependent vasoconstriction seems more prominent in the venous vasculature. A better understanding of how ET-1 is synthesized and how ETA and ETB receptors interact could help design better pharmacological agents in the treatment of cardiovascular diseases where targeting the ET-1 system is indicated.

Characterization and immunohistochemical localization of nucleoside triphosphate diphosphohydrolase (NTPDase) in pig adrenal glands (presence of a non-sedimentable isoform).

Considering that adrenal glands possess a variety of purinoceptors associated with various cell types and that some of these cells (chromaffin cells) secrete large amounts of adenine nucleotides, it was of interest to localize nucleoside triphosphate diphosphohydrolase (NTPDase) in these glands and to define the biochemical characteristics of this ectonucleotidase. Immunolocalization produced a moderate reaction in capsula and medulla, with no signal in zona glomerulosa and zona reticularis. In contrast, a very strong reaction was found in zona fasciculata. Biochemical analysis of particulate fractions isolated from whole glands revealed high levels of ATPase and ADPase activities. This appeared to be attributable to the NTPDase since the level of ADPase was as high as ATPase. Both ATPase and ADPase activities were similarly inhibited by sodium azide. Additionally electrophoretograms with these two substrates showed comparable patterns. Western blots with 'Ringo', an antibody that recognizes the different isoforms of mammalian NTPDases, showed the presence of isoforms of NTPDases at 54 and 78 kDa, respectively. Interestingly, the 54 kDa isoform remains in the supernatant of a chromaffin granule lysate after ultracentrifugation. Up until now little interest has been given to the relationship between adrenal medulla and cortex. Presence of purinoceptors and ectonucleotidases in both these regions together with the effects of ATP in vivo and in vitro in different species indicate that purines play a significant role in adrenal glands.

Function of the endothelin(B) receptor in cardiovascular physiology and pathophysiology.

One of the two receptors by which the potent vasoactive effects of endothelin (ET)-1 are mediated is the ET(B) receptor (ET(BR)), which is found in several tissues, but, more importantly from a cardiovascular point of view, on the endothelial cell. The endothelial cell also has the unique capability of releasing ET-1, as well as other factors, such as the endothelial-derived relaxing factors and prostacyclin, which counteract the myotropic effects of the peptide. The secretory and contractile responses to ET-1 rely on G-protein-coupled ET(BR)s, as well as ET(A)-G-protein-coupled receptor-like proteins. The mitogenic properties of ET-1 via ET(A) receptors (ET(AR)s) coupled to mitogen-activated protein kinases and tyrosine kinases on the vascular smooth muscle may occur in conjunction with the anti-apoptotic characteristics of the endothelial ET(BR)s. Interestingly, most of the relevant antagonists and agonists for both ET(AR)s and ET(BR)s have been developed by the pharmaceutical industry. This highlights the therapeutical potential of compounds that act on ET receptors. In normal as well as in physiopathological conditions, the ET(BR) plays an important role in the control of vascular tone, and must be taken into account when using ET receptor antagonists for the treatment of cardiovascular diseases. For the management of congestive heart failure, renal failure and primary pulmonary hypertension, the most recent literature supports the use of selective ET(AR) antagonists rather than mixed antagonists of ET(AR)s and ET(BR)s. Nonetheless, validation of this view will have to await the first clinical trials comparing the actions of ET(A) to mixed ET(A)/ET(B) receptor antagonists.

Phosphoramidon-sensitive effects of big endothelins in the perfused rabbit kidney.

The enzymatic conversion of human big endothelins (1, 2, and 3) to their respective active metabolites (endothelin-1, -2, and -3) was investigated in the perfused rabbit kidney through the pressor- and eicosanoid-releasing properties of these peptides. Intra-arterial bolus injections of endothelin-1 and -2 (5-50 pmol), endothelin-3 (100-250 pmol), and big endothelin-1 and -2 (100-250 pmol) into the kidney produced dose-dependent increases of perfusion pressure, whereas big endothelin-3 was inactive at doses up to 1,000 pmol. Endothelin-1 and -2 (10 nM), endothelin-3 (100 nM), and big endothelin-1 and -2 (100 nM) are potent enhancers of prostacyclin release without inducing any release of thromboxane B2 in the perfused kidney. In contrast, big endothelin-3 did not trigger the release of eicosanoids. A metalloprotease inhibitor, phosphoramidon (100 microM, 60 minutes), reduced the prostanoid release and pressor responses induced by big endothelin-1 and -2 without affecting the response induced by endothelin-1, -2, and -3. These results suggest the presence of a phosphoramidon-sensitive endothelin converting enzyme that converts the precursors of endothelin-1 and -2, but not of endothelin-3, in the renal vasculature of the rabbit.

DuP 753 is a specific antagonist for the angiotensin receptor.

2-n-Butyl-4-chloro-5-hydroxy-methyl-1-[(2'-(1H)-tetrazol-5-yl)biph enyl-4- yl)methyl]imidazol potassium salt (DuP 753) is a nonpeptide angiotensin II receptor antagonist that inhibits the contractile effects of angiotensin II competitively and shows pA2 values of 8.27 on the rabbit aorta and jugular vein, 8.66 on the rat portal vein and stomach, 8.19 on the rat urinary bladder, and 8.36 on human colon, ileum, and urinary bladder. This agent (more than 10(-5) M) exhibits no agonistic activity and does not affect the contractile effects of norepinephrine, acetylcholine, bradykinin, desArg9-bradykinin, substance P, neurokinin A, neurokinin B, or bombesin in the various tissues. The present results demonstrate that DuP 753 is a potent nonpeptide antagonist with high affinity, specificity, and selectivity for the angiotensin receptor.

ET(B) receptor and nitric oxide synthase blockade induce BQ-123-sensitive pressor effects in the rabbit.

Endothelin-1 (0.25 nmol/kg, injected into the left cardiac ventricle) induces a protracted increase of mean arterial pressure that is significantly reduced by the selective ET(A) receptor antagonist BQ-123 (1 and 10 mg/kg) in the anesthetized rabbit. The sole administration of the selective ET(B) antagonist BQ-788 (0.25 mg/kg) induces a pressor response abolished by BQ-123 (1 mg/kg). Concomitant to the increase in mean arterial pressure, BQ-788 induces a significant increase in plasma levels of endothelin-1 and its precursor big endothelin-1. The nitric oxide synthase inhibitor N omega-nitro-L-arginine methyl ester (L-NAME; 10 mg/kg) also increases arterial blood pressure, and the response is reduced dose-dependently by BQ-123 (1 and 10 mg/kg). In addition, the administration of BQ-788 in the presence of L-NAME induced a further increase in arterial blood pressure. The duration of the pressor response to L-NAME is also significantly reduced by an endothelin-converting enzyme inhibitor, phosphoramidon (10 mg/kg). Finally, L-NAME induces an increase in plasma levels of big endothelin-1 but not endothelin-1. Our results illustrate that blockade of either nitric oxide synthase or ET(B) receptors triggers a raise in plasma levels of endothelin-1 or its precursor. These later moieties are suggested to be significantly involved, through the activation of ET(A) receptors, in the pressor effects of L-NAME and BQ-788 in the anesthetized rabbit.

Processing of proendothelin-1 by human furin convertase.

Endothelin-1 (ET-1) is the most potent vasoactive peptide known to date. The peptide is initially synthesized as an inactive precursor (proET-1) which undergoes proteolysis at specific pairs of basic amino acids to yield bigET-1. Production of ET-1 then proceeds by cleavage of bigET-1 by the endothelin converting enzyme (ECE). Here, we demonstrate that the in vitro cleavage of proET-1 by furin, a mammalian convertase involved in precursor processing, produced bigET-1. Upon further processing, bigET-1 was converted to biologically active ET-1. Furthermore, we demonstrate that the furin inhibitor, decanoyl-Arg-Val-Lys-Arg chloromethylketone, abolished production of ET-1 in endothelial cells.

Novel inhibitors of nucleoside triphosphate diphosphohydrolases: chemical synthesis and biochemical and pharmacological characterizations.

To elucidate the physiological role played by nucleoside triphosphate diphosphohydrolase (NTPDase; EC 3.6.1.5), adenine nucleotide analogues, modified on the purine ring, have been synthesized and tested as potential inhibitors. Resistance of ATP analogues to hydrolysis and their potency as NTPDase inhibitors were evaluated. For this purpose, a particulate fraction isolated from bovine spleen was used as the enzyme source. Among the synthesized analogues, 8-thiobutyladenosine 5'-triphosphate (8-BuS-ATP) was found to be the most effective nonhydrolyzable competitive inhibitor, with an estimated K(i) of 10 microM. This nonhydrolyzable analogue did not exert any P2X-receptor-mediated effect on endothelium-denuded blood vessels, from the guinea pig mesenteric bed. In agreement with this observation, infusion of the analogue did not cause any significant blood pressure variations of the precontracted vessel. Because in previous studies on isolated turkey erythrocytes and rat astrocytes 8-BuS-ATP was not able to trigger any P2Y(1)-receptor-mediated effect, it therefore appears that this NTPDase inhibitor does not interfere with purinergic receptors.

Different pharmacological profiles of big-endothelin-3 and big-endothelin-1 in vivo and in vitro.

1. Human big-endothelin-1 (big-ET-1) and endothelin-1 (ET-1) are equipotent as pressor agents and produce a significant change in mean arterial blood pressure (MAP) in anaesthetized guinea-pigs (2 nmol kg-1: peak delta MAP: 23 +/- 6 mmHg and 26 +/- 5 mmHg, respectively). 2. Unlike big-ET-1, big-endothelin-3 (big-ET-3) (10 and 20 nmol kg-1) induces no pressor responses whereas endothelin-3 (ET-3) at 2 nmol kg-1 induces a significant increase of blood pressure in anaesthetized guinea-pigs (peak delta MAP: 27 +/- 5 mmHg) with a shorter duration than ET-1 and big-ET-1. 3. Big-ET-1 at concentrations 40 times higher than those required for ET-1 (2.5 nM) releases prostacyclin (PGI2) (maximal release: 2.7 +/- 0.8 ng ml-1; 2.9 +/- 0.9 ng ml-1, respectively) and thromboxane B2 (TxB2) (maximal release: 6.7 +/- 1.3 ng ml-1; 6.8 +/- 1.1 ng ml-1, respectively) from guinea-pig perfused lungs. ET-3 (2.5 nM) is also a potent releaser of PGI2 and TxB2 from the guinea-pig lungs (maximal release: PGI2: 2.4 +/- 1.0 ng ml-1; TxB2: 3.8 +/- 0.6 ng ml-1). Conversely, big-ET-3 (100 nM) does not increase basal release of eicosanoids. 4. Phosphoramidon (50 microM), a metalloprotease inhibitor, markedly reduced the eicosanoid releasing properties of big-ET-1 (n = 4, P less than 0.01) in guinea-pig perfused lungs without affecting the release stimulated by ET-1. 5. Our results suggest that big-ET-1 is converted to ET-1 via a phosphoramidon-sensitive endothelin converting enzyme (ECE) to release eicosanoids. The ECE is present in the guinea-pig pulmonary vasculature. Furthermore, our results suggest that the ECE activity is specific for big-ET-1 and may not convert big-ET-3 to its active metabolite, ET-3.

Role of ETB and B2 receptors in the ex vivo platelet inhibitory properties of endothelin and bradykinin in the mouse.

1. We have developed a model to study the inhibitory properties of endogenous autacoids triggered by systemically-administered vasoactive peptides, on platelet aggregation ex vivo in the mouse. 2. Adenosine diphosphate (ADP) (0.5-10 microM) induces a concentration-dependent aggregation of platelet-rich plasma derived from C57BL/6 mice. Intravenously-administered endothelin-1 (0.01-1 nmolx kg(-1)), the selective ETB agonist, IRL-1620 (0.0 -1 nmol x kg(-1)) or bradykinin ( 1-100 nmol x kg(-1)) significantly reduced in a dose-dependent fashion the ADP-induced platelet aggregation. 3. The non-selective cyclo-oxygenase (COX) inhibitor, indomethacin, a selective COX-2 inhibitor NS-398 or the prostacyclin synthase inhibitor, tranylcypromine (10 mg x kg(-1)), markedly reduced the inhibitory properties of endothelin-1, whereas only a combination of both indomethacin, NS-398 or tranylcypromine and L-NAME (10 mg x kg(-1)) were required to abolish the response to bradykinin. 4. An ETB-selective antagonist (BQ-788) or knockout of the B2 receptor gene (in B2 knockout mice) abolishes the platelet inhibitory properties of endothelin-1 and bradykinin, respectively. 5. Our results suggest that intravenously-administered endothelin-1 and bradykinin, through ETB and B2 receptor activation, respectively, inhibit platelet aggregation ex vivo in the mouse. The inhibitory properties of endothelin-1 require the activation of COX-2 and the subsequent generation of prostacyclin. In addition to the two previously mentioned factors, nitric oxide is required for the anti-aggregatory effects of bradykinin.

Kinins act on B1 or B2 receptors to release conjointly endothelium-derived relaxing factor and prostacyclin from bovine aortic endothelial cells.

1. Bradykinin (Bk) induced the coupled release of endothelium-derived relaxing factor (EDRF) and prostacyclin (PGI2) from bovine aortic endothelial cells grown in culture. The B2 kinin receptor antagonist, [D-Arg0,Hyp3,Thi5,8,D-Phe7]-Bk, abolished this release by Bk. 2. Des-Arg9-Bk, a B1 kinin receptor agonist, also induced the release of EDRF and PGI2, but much higher concentrations were required to obtain a similar release to that induced by Bk. 3. [Leu8],des-Arg9-Bk, a B1 receptor antagonist, significantly reduced the response to des-Arg9-Bk without affecting the release induced by Bk. 4. The release of EDRF and PGI2 induced by arachidonic acid or ADP was not significantly affected by the B2 or the B1 antagonist. 5. We conclude, therefore, that Bk and des-Arg9-Bk were acting respectively on B2 and B1 bradykinin receptors. 6. The possible role of kinin receptors in the release of EDRF and PGI2 from endothelial cells is discussed.

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.

Pharmacology of two novel mixed ETA/ETB receptor antagonists, BQ-928 and 238, in the carotid and pulmonary arteries and the perfused kidney of the rabbit.

1. In the present study, we have pharmacologically characterized two novel mixed endothelin ETA/ETB receptor antagonists, namely BQ-928 and BQ-238, in ETA and ETB preparations, the rabbit carotid artery (RbCA) and the rabbit pulmonary artery (RbPA), respectively. These two antagonists were compared to established ETA (BQ-123 and BMS 182874), ETB (BQ-788) and mixed ETA/ETB (SB 209670) receptor antagonists. 2. In the RbCA, the ETA monoreceptor preparation, BQ-238 and BQ-928 had apparent affinities (pA2) of 7.42 +/- 0.22 and 7.22 +/- 0.18, respectively, BQ-788 being inactive in this preparation. In the ETB monoreceptor preparation, the RbPA (when IRL-1620 was used as an ETB receptor agonist), the pA2 for BQ-238 was 7.05 +/- 0.14 and for BQ-928 was 8.43 +/- 0.04. BQ-123 and BMS 182874 were inactive in this preparation. Similar to SB 209670, BQ-238 but not BQ-928 had a higher affinity for the ETA than the ETB receptor. 3. All of the antagonists were tested for their ability to block and reverse endothelin-l-induced vasoconstrictions in the rabbit perfused kidney. In this preparation endothelin-1-induced increases in vascular resistance have been shown to be mediated solely by ETA receptors. All compounds (except BQ-788) blocked the pressor effects of endothelin within the kidney; the calculated IC50 values for BQ-123, BMS 182874, SB 209670, BQ-928 and BQ-238 were 0.4 microM, 2 microM, 0.01 microM, 0.4 microM and 0.09 microM, respectively. 4. In all experiments in the rabbit perfused kidney, endothelin-1 was readministered for a third time, 60 min following cessation of infusion of the above-mentioned antagonists. The response to the third infusion of endothelin-1 following cessation of infusion of BQ-123, BMS 182874 and SB 209670 was not significantly different from that to the third infusion of endothelin in control conditions. However, the response to endothelin-1 was significantly higher than control in tissues pre-infused with BQ-788 or BQ-928 (56 +/- 9 and 41.6 +/- 15%, respectively, n = 8 each, P < 0.05). 5. Our results suggest that in a system where ETA receptor activation is responsible for vasoconstriction and ETB-receptor activation for vasodilatation. ETA receptor selective antagonists or mixed ETA/ETB receptor antagonists which possess high affinity for ETA receptors do not induce hyperresponsiveness to endothelin-1. In contrast, ETB selective antagonists or mixed antagonists possessing a high affinity for ETB receptors (such as BQ-928) interfere with the ETB-receptor-dependent physiological antagonism of endothelin-1-induced pressor responses in these same tissues.

Characterization of receptors for endothelins in the perfused arterial and venous mesenteric vasculatures of the rat.

1. Endothelin-1 and -3 induced marked arterial and venous constrictions in the perfused mesenteric vasculature of the rat with endothelin-3 being at least 20 times less active than endothelin-1, on both arterial and venous sides of the vasculature. 2. Two ETB selective agonists, BQ-3020 and IRL 1620 (500 pmol), induced weak constrictions of the venous mesenteric vasculature and were inactive in the arterial side at doses up to 1000 pmol. 3. In mesenteric vasculatures precontracted with either methoxamine (arterial side) or the thromboxane A2-mimetic, U46619 (venous side), acetylcholine or bradykinin produced vasodilations of both arterial and venous vessels, whereas endothelin-3 induced vasodilations only on the arterial side. 4. A selective ETA receptor antagonist, BQ-123, blocked, in a concentration-dependent and reversible fashion, the vasoconstrictions induced by endothelin-1 on both sides of the mesenteric circulation (IC50; arterial side: 0.013 microM; venous side: 0.032 microM). 5. In contrast, the vasodilator responses induced by endothelin-3 on the arterial side of the precontracted mesenteric vasculature were not affected by BQ-123. 6. The present study illustrates the presence of ETA receptors which are responsible for vasoconstriction by endothelins in the arterial and venous mesenteric vasculatures. Furthermore, we suggest that the vasodilations induced by endothelin-3 in the arterial vasculature uniquely, are ETB receptor-mediated.

Block of endothelin-1-induced release of thromboxane A2 from the guinea pig lung and nitric oxide from the rabbit kidney by a selective ETB receptor antagonist, BQ-788.

1. The present study characterizes the receptors responsible for endothelin-1-induced release of thromboxane A2 from the guinea pig lung and of endothelium-derived nitric oxide from the rabbit perfused kidney, by the use of the selective ETA receptor antagonist, BQ-123, and a novel selective ETB receptor antagonist, BQ-788. 2. In the guinea pig perfused lung, endothelin-1 (ET-1) (5 nM) induced a marked increase of thromboxane A2 which was reduced by 17 +/- 5.0, 70 +/- 1.0 and 93 +/- 1.2% by BQ-788 infused at concentrations of 1, 5 and 10 nM respectively. In contrast, BQ-123 (0.1 and 1.0 microM) had little or no effect on the ET-1-induced release of thromboxane A2. 3. In the same perfused model, the selective ETB agonist, IRL 1620 (50 nM), stimulated the release of thromboxane A2, but not prostacyclin. The eicosanoid-releasing properties of IRL 1620 were abolished by BQ-788 at 10 nM, yet were unaffected by BQ-123 (1 microM). 4. In the rabbit perfused kidney, BQ-788 (10 nM) potentiated the increase of perfusion pressure induced by endothelin-1 (1, 5 and 10 nM) by approximately 90%, but not that induced by angiotensin II (1 microM). Furthermore, the selective ETB receptor antagonist did not reduce the release of prostacyclin triggered by either peptide. 5. In another series of experiments, pretreatment of the perfused kidney with a nitric oxide synthase inhibitor, L-NAME (100 microM), potentiated the pressor responses to both endothelin-1 and angiotensin II. Under L-NAME treatment, BQ-788 did not further potentiate the pressor response to endothelin-1. 6 Our results illustrate the predominant role of ETB receptor activation in the release of thromboxane A2 and nitric oxide triggered by endothelin-l in the guinea pig perfused lung and rabbit kidney respectively.

Role of R-type calcium channels in the response of the perfused arterial and venous mesenteric vasculature of the rat to platelet-activating factor.

1. The vasoactive properties of platelet-activating factor (PAF) were studied in the arterial and venous vasculature of the rat double-perfused mesenteric bed. Although PAF (0.01-0.3 pmol) induced a dose-dependent vasodilatation of the arterial mesenteric vasculature, it triggered only vasoconstrictions on the venous side, with an intact endothelium as bradykinin induced a significant venodilatation. 2. NG-nitro-L-arginine methyl ester (L-NAME, 100 microM), a nitric oxide synthase inhibitor, markedly reduced the vasodilatation induced by PAF in the arterial mesenteric vasculature and potentiated the contractile responses of the venous side to the same agent. 3. The PAF antagonist, WEB-2170, markedly reduced the response to PAF on both sides of the mesenteric vasculature. However, the IC50 of WEB-2170 against PAF was reached at a much higher concentration (1 x 10(-8) M) on the arterial side than on the venous side (5.3 x 10(-11) M). Furthermore, a second antagonist of PAF receptors, SRI-63441, although being less potent on the venous vasculature than WEB-2170, was equipotent in antagonizing the venoconstriction and the arterial dilatation induced by PAF (IC50 of SRI-63441, arterial side: 2.9 x 10(-9) M; venous side: 3.1 x 10(-9) M). 4. The dual L- and R-calcium channel blocker, isradipine (PN 200-110), but not the L-type calcium channel blocker, nifedipine, markedly reduced the PAF-induced vasoactive properties on both sides of the mesenteric vasculature. 5. Our results illustrate the differential vasoactive properties of PAF in the mesenteric vasculature of the rat. These vasoactive responses occur following activation of specific receptors for PAF or,alternatively, through activation of R-type calcium channels.