In porcine aortic endothelial cells, the 21-amino acid peptide endothelin-1 (ET-1) is formed from a 39-amino acid intermediate called "big endothelin-1" (big ET-1) by a putative ET-converting enzyme (ECE) that cleaves the 39-mer at the bond between Trp-21 and Val-22. Since big ET-1 has only 1/100-1/150th the contractile activity of ET-1, inhibition of ECE should effectively block the biological effects of ET-1. Big ET-1 injected intravenously into anesthetized rats produces a sustained pressor response that presumably is due to conversion of big ET-1 into ET-1 by ECE. We determined the type of protease activity responsible for this conversion by evaluating the effectiveness of protease inhibitors in blocking the pressor response to big ET-1 in ganglion-blocked anesthetized rats. The serine protease inhibitor leupeptin, the cysteinyl protease inhibitor E-64, and the metalloprotease inhibitors captopril and kelatorphan were all ineffective at blocking the pressor response to big ET-1. However, the metalloprotease inhibitors phosphoramidon and thiorphan dose-dependently inhibited the pressor response to big ET-1, although phosphoramidon was substantially more potent than thiorphan. None of the inhibitors blocked the pressor response to ET-1 and none had any effect on mean arterial pressure when administered alone. In a rabbit lung membrane preparation, ECE activity was identified that was blocked by the metalloprotease inhibitors phosphoramidon and 1,10-phenanthroline in a concentration-dependent manner. This enzyme converted big ET-1 to a species of ET that comigrated on HPLC with ET-1 and produced an ET-like contraction in isolated rat aortic rings. Our results suggest that the physiologically relevant ECE is a metalloprotease.In 1988, Yanagisawa and coworkers (1) reported on the isolation and characterization of a peptide, endothelin (ET), from the culture supernatant of porcine aortic endothelial cells. Now referred to as endothelin-1 (ET-1), this peptide contracts vascular smooth muscle in vitro and produces a sustained pressor response in vivo. In porcine aortic endothelial cells, the 21-amino acid peptide ET-1 is formed from a 39-amino acid intermediate called "big endothelin-1" (big ET-1) by a putative ET-converting enzyme (ECE) that hydrolyzes the 39-mer at the bond between Trp-21 and Val-22 to yield ET-1-(1-21) and the C-terminal fragment, big ET-1-(22-39) (2). Since big ET-1 has only 1/100-1/150th the contractile activity of ET-1 (3), inhibition of ECE should effectively block the biological effects of ET-1. This could be an important therapeutic strategy for the treatment of hypertension, acute renal failure, myocardial infarction, and coronary and cerebral vasospasm-diseases in which an overproduction of ET might play an important pathophysiological role (4-8).Serine-, cysteinyl-, aspartyl-, and metalloproteases have all been identified as processing enzymes responsible for the conversion of precursor proteins to bioactive peptides in mammalian cells (9). In their original report on the isolati...
Cyclic analogues of angiotensin II (AII) were synthesized by connecting the side chains of residues 3 and 5 via a disulfide bridge. Appropriate conformational constraints afforded an analogue, [Hcy3,5]AII, having high contractile activity (pD2 = 8.48 vs 8.81 for AII) and excellent binding affinity (IC50 = 2.1 nM vs 2.2 nM for AII). This type of cyclization was also used to prepare a highly potent AII antagonist, [Sar1,Hcy3,5,Ile8]AII (pA2 = 9.09 vs 9.17 for [Sar1, Ile8]AII; IC50 = 0.9 nM vs 1.9 nM for [Sar1,Ile8]AII). Model building suggests that this ring structure is consistent with a receptor-bound conformation having any of a variety of three-residue turns, including a gamma-turn. In contrast, the receptor-bound conformation of AII does not appear to accommodate a beta-turn or an alpha-helix which includes residues 3-5.
A series of 5-[1-[4-[(4,5-disubstituted-1H-imidazol-1-yl)methyl]- substituted]-1H-pyrrol-2-yl]-1H-tetrazoles and 5-[1-[4-[(3,5-dibutyl-1H-1,2,4-triazol-1-yl)methyl]-substituted]- 1H-pyrrol-2-yl]-1H-tetrazoles were investigated as novel AT1-selective angiotensin II receptor antagonists. Computer-assisted modeling techniques were used to evaluate structural parameters in comparison to the related biphenyl system. New synthetic procedures have been developed to prepare the novel compounds. The best antagonists in this series had IC50 values (rat uterine membrane receptor binding) in the 10(-8) M range and corresponding pA2 in isolated organ assay (rabbit aorta rings). Structure-activity relationships indicate some similarities with the finding in the biphenyl system. Substitution on the pyrrole ring modulates activity. Compound 5 antagonized angiotensin-induced blood pressure increase when administered to conscious rat at 30 mg/kg per os.
A series of analogues of the recently reported angiotensin II (AII) antagonist [Sar1]AII-(1-7)-amide or des-Phe8[Sar1]AII (3) have been prepared by solid-phase synthesis and purified by reverse-phase liquid chromatography. The agonist and antagonist properties of these carboxy-truncated analogues of AII were determined in the isolated rabbit aorta assay. In the analogues tested, replacement of aspartic acid in position 1 by sarcosine was found necessary to produce significant antagonist activity. At position 7 of the des-Phe8 analogues, prolinamide could be replaced by proline without significant change in the biological activity. However, substitution of 7-prolinamide by either glycinamide or sarcosinamide provided inactive peptides. Methylation of the 4-tyrosine in [Sar1]AII-(1-7)-NH2 preserved the antagonist potency in isolated rabbit aorta. Deletion of the proline at position 7 resulted in inactive hexapeptides, both in the Asp1 and Sar1 series. However synthesis of the N,N-dimethyl amide at the N-terminus afforded hexapeptide [Sar1]AII-(1-6)-N(CH3)2 (10) with a pA2 value of 7.05. All the antagonistic peptides synthesized were fully reversible, competitive antagonists in vitro. These findings indicate that the structural requirements for receptor blockade by these C-truncated analogues are quite stringent with respect to the nature of the amino acid at positions 1 and 6/7. The analogues 2, 3, 7, 10, 11 (saralasin), and 12 (sarmesin) were tested in vivo in the anesthetized rat and were found to inhibit the AII pressor response. In addition, 3 inhibited angiotensin II stimulated aldosterone release from isolated rat adrenal zona glomerulosa cells and had no agonist activity by itself at the doses tested. Interestingly, analogue 3, when injected intracerebroventricularly in conscious rats, failed to antagonize the dipsogenic response to an angiotensin II icv injection and this reflects some heterogeneity in the AII receptor population. Peptide 3 is the first example of an antagonist that discriminates between peripheral and brain receptor subtypes.
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