Cyclic expression of endothelin-converting enzyme-1 mediates the functional regulation of seminiferous tubule contraction.

The potent smooth muscle agonist endothelin-1 (ET-1) is involved in the local control of seminiferous tubule contractility, which results in the forward propulsion of tubular fluid and spermatozoa, through its action on peritubular myoid cells. ET-1, known to be produced in the seminiferous epithelium by Sertoli cells, is derived from the inactive intermediate big endothelin-1 (big ET-1) through a specific cleavage operated by the endothelin-converting enzyme (ECE), a membrane-bound metalloprotease with ectoenzymatic activity. The data presented suggest that the timing of seminiferous tubule contractility is controlled locally by the cyclic interplay between different cell types. We have studied the expression of ECE by Sertoli cells and used myoid cell cultures and seminiferous tubule explants to monitor the biological activity of the enzymatic reaction product. Northern blot analysis showed that ECE-1 (and not ECE-2) is specifically expressed in Sertoli cells; competitive enzyme immunoassay of ET production showed that Sertoli cell monolayers are capable of cleaving big ET-1, an activity inhibited by the ECE inhibitor phosphoramidon. Microfluorimetric analysis of intracellular calcium mobilization in single cells showed that myoid cells do not respond to big endothelin, nor to Sertoli cell plain medium, but to the medium conditioned by Sertoli cells in the presence of big ET-1, resulting in cell contraction and desensitization to further ET-1 stimulation; in situ hybridization analysis shows regional differences in ECE expression, suggesting that pulsatile production of endothelin by Sertoli cells (at specific "stages" of the seminiferous epithelium) may regulate the cyclicity of tubular contraction; when viewed in a scanning electron microscope, segments of seminiferous tubules containing the specific stages characterized by high expression of ECE were observed to contract in response to big ET-1, whereas stages with low ECE expression remained virtually unaffected. These data indicate that endothelin-mediated spatiotemporal control of rhythmic tubular contractility might be operated by Sertoli cells through the cyclic expression of ECE-1, which is, in turn, dependent upon the timing of spermatogenesis.     

CGS 34043: a non-peptidic, potent and long-acting dual inhibitor of endothelin converting enzyme-1 and neutral endopeptidase 24.11

Endothelin-1 (ET- 1) is a potent vasoconstrictor. Its biosynthesis is catalyzed by endothelin converting enzyme (ECE). In contrast, atrial natriuretic peptide (ANP) is a potent vasorelaxant and diuretic, and it is mainly degraded by neutral endopeptidase 24.11 (NEP). Therefore, compounds that can suppress the production of ET-1 by inhibiting ECE while simultaneously potentiating the levels of ANP by inhibiting NEP may be novel agents for the treatment of cardiovascular and renal dysfunction. CGS 34043 is one such compound, which inhibited the activities of ECE-1a and NEP with IC50 values of 5.8 and 110 nM, respectively. In vivo, it inhibited the pressor response induced by big ET-1, the precursor of ET-1, dose-dependently in rats, and the inhibition was sustained for at least 2 hr. In addition, CGS 34043 increased plasma ANP by 150% up to 4 hr after an intravenous dose of 10 mg/kg in conscious rats infused with ANP. However, this compound had no effect on the angiotensin I-induced pressor response. These results demonstrate that CGS 34043 is a potent and long-lasting dual inhibitor of ECE-1 and NEP. Consequently, it may be beneficial for the treatment of diseases in which an overproduction of ET-1 and/or enhanced degradation of ANP plays a pathogenic role. The activity of CGS 34753, an orally active prodrug of CGS 34043, is also described.     

Identification of endothelin converting enzyme in bovine lung membranes using a new fluorogenic substrate.

An enzyme partially purified from bovine lung membranes appears to be endothelin converting enzyme (ECE). This enzyme specifically cleaves big endothelin-1 (big ET-1) at the proper site, between Trp21 and Val22, with maximum activity at pH 7.5 and with a Km of roughly 3 microM, to produce endothelin-1 (ET-1) and C-terminal peptide (CTP). This same enzyme hydrolyzes the fluorogenic substrate succinyl-Ile-Ile-Trp-methylcoumarinamide to release the highly fluorescent 7-amino-4-methylcoumarin. The peptide derivative has the same amino acid sequence as big ET-1 and is a good substrate with a Km of about 27 microM. This enzyme is a metalloproteinase. It is not inhibited by five common proteinase inhibitors (pepstatin A, PMSF, NEM, E-64 and thiorphan) but it is inhibited by phosphoramidon and chelating compounds. The apoenzyme is restored to nearly full activity by a zinc-EDTA buffer with pZn = 13.     

Characterization of phosphoramidon-sensitive metalloproteinases with endothelin-converting enzyme activity in porcine lung membrane

Endothelin-1 (ET-1), a 21 amino-acid potent vasoconstrictor peptide, is produced from the biologically inactive intermediate big ET-1 via an endoproteolytic cleavage between Trp-21 and Val-22 by endothelin converting enzyme (ECE). cDNA sequence analysis predicts that the two other members of the endothelin family, ET-2 and ET-3, are also generated from the corresponding intermediates called big ET-2 and big ET-3, respectively. The metalloproteinase inhibitor phosphoramidon inhibited the conversion of big ET-1 into mature ET-1 both in vivo and in cultured endothelial cells, suggesting that ECE may be a neutral metalloproteinase. In this study, we solubilized and partially purified ECE from the membrane fraction of porcine lung. Using gel filtration chromatography, we separated two distinct ECE activities, designated M1 (apparent molecular mass approx. 300 kDa) and M2 (approx. 65 kDa). Optimum pH for the cleavage of big ET-1 by M1 and M2 was 7.0 and 7.5, respectively. M1 efficiently converted human big ET-1(1–38) to ET-1, but not human big ET-2(1–37) or human big ET-3(1–41)-amide. In contrast, M2 converted both big ET-1 and big ET-2, but not big ET-3. M1 was inhibited by phosphoramidon (IC₅₀ approx. 1 μM) but not by thiorphan or bacitracin. In contrast, M2 was inhibited by much lower concentrations of phosphoramidon (IC₅₀ approx. 0.3 nM), as well as by thiorphan and bacitracin. ECE activity in M1 was able to bind to a concanavalin A-agarose column and was eluted by α-methyl-d-glucoside, indicating that the ECE is glycosylated. From these results, M1 and M2 from the porcine lung membrane are similar to the candidate of ECE in endothelial cells and neutral endopeptidase in kidney (EC 3.4.24.11), respectively. Taken in conjunction with the previous finding that neither thiorphan nor bacitracin affected the conversion of endogenously synthesized big ET-1 in cultured endothelial cells, we conclude that physiologically relevant ECE found in the endothelial cells is more similar to M1 than to M2.     

Biochemical properties of endothelin converting enzyme in renal epithelial cell lines.

This is the first report clearly demonstrating the presence of endothelin (ET) converting enzyme (ECE) in non-vascular cells (renal epithelial cell lines, MDCK and LLC-PK1). ECEs derived from these epithelial cells were very similar to the endothelial ECE in the following biochemical properties: 1) The optimum pH was 7.0; 2) the Km value for big ET-1 was approximately 30 microM; 3) the enzyme was potently inhibited by EDTA, o-phenanthroline and phosphoramidon; and 4) the enzyme did not convert big ET-2 or big ET-3. These data suggest that phosphoramidon-sensitive ECE is involved in the processing of big ET-1 to ET-1 in the renal tubule.     

Importance of the C-terminal region of big endothelin-1 for specific conversion by phosphoramidon-sensitive endothelin converting enzyme

Based on our previous findings that phosphoramidon-sensitive endothelin (ET) converting enzyme (ECE) converts human big ET-1 but does not big ET-3, we investigated structural requirement for substrate peptide. We prepared shorter peptides of big ET-1 and measured hydrolysis of the Trp-Val bond of these peptides. Relative hydrolysis ratios of big ET-1(1-38), (1-37), (16-37), (1-31) and (17-26) were 1, 1.15, 3.71, 0.01 and 0, respectively. In addition, big ET-2 and big ET-3 were not significantly converted by ECE. These results suggest that the carboxyl-terminal sequence at residues 32-37 of big ET-1 is important for conversion, whereas the amino-terminal disulfide loop structure appears to interfere with access of ECE to big ET-1.     

Characterization of the contractile and relaxant action of the endothelin-1 precursor, big endothelin-1, in the isolated rat basilar artery

The presence of functional endothelin converting enzyme (ECE) activity in basilar artery ring segments was investigated by measuring the contractile and relaxant effects of big endothelin (ET)-1. Under resting tension conditions cumulative application of big ET1-1 elicited a concentration-related contraction with the concentration-effect curve (CEC) shifted to the right against ET-1 by a factor of 31 and 29 in segments with the endothelium intact or mechanically removed, respectively. Preincubation with the ET(A) receptor antagonist, BQ123, induced an apparently parallel rightwards shift without affecting the maximum contraction. This shift was more pronounced for ET-1 than for big ET-1. With the putative ECE inhibitor phosphoramidon (10(-3) M) in the bath a small rightwards shift of the CEC for big ET-1 was observed in control segments and a more marked one in de-endothelialized segments. In segments precontracted with prostaglandin (PG) F(2alpha) big ET-1 induced a significant although transient relaxation whereas ET-1 did not. However, in the presence of BQ123 both ET-1 and big ET-1 elicited concentration-related relaxation with a significantly higher maximum effect obtained with big ET-1. The potency was 13 fold higher for ET-1, which is markedly less than that found for contraction. The results, therefore, suggest 1) the presence of functional ECE-activity in the rat basilar artery wall, and 2) differences in the functional ECE activity located in the endothelium and media.     

Analysis of big endothelin-1 digestion by cathepsin D

Digestion of big endothelin (ET)-1 by cathepsin D, which is the only substantially identified protease showing ET converting enzyme activity, was characterized. Increased doses of cathepsin D showed decrease of immunoreactive (ir-) ET produced from big ET-1. Time course of big ET-1 conversion showed marked increase of ir-ET in a relatively short period, but further incubation resulted in the decrease of ir-ET. Incubation at various pHs with different doses of cathepsin D revealed that low doses of cathepsin D yielded the maximum production of ir-ET at pH 3.5-4.0, but higher doses of cathepsin D showed a bimodal curve of ir-ET production, which may be due to degradation of ir-ET. HPLC analysis revealed that cathepsin D cleaves Asn18-Ile19 bond in addition to Trp21-Val22 bond of big ET-1. These data suggests cathepsin D is not a physiological endothelin converting enzyme.     

Purification and characterization of putative endothelin converting enzyme in bovine adrenal medulla: evidence for a cathepsin D-like enzyme

A specific and sensitive assay has been established for measurement of endothelin converting activity in a tissue extract. This assay is based on measuring endothelin-1 generated from big endothelin-1 by endothelin converting enzyme (ECE) with radioimmunoassay using an endothelin C-terminal specific antibody. By using this assay, we purified and characterized ECE in bovine adrenomedullary chromaffin granules ECE was purified over 3,000 times by a combination of DEAE, hydrophobic and gel filtration chromatography. A molecular weight of ECE was estimated to be approximately 30,000 by gel filtration. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that ECE had three major components with estimated molecular weights of 45,000, 30,000 and 15,000 like bovine spleen cathepsin D. ECE had a pH optimum at 3.5 and was inhibited by pepstatin. These results strongly suggest that ECE is a cathepsin D-like aspartic protease.     

A simple method for measurement of phosphoramidon-sensitive endothelin converting enzyme activity.

We have developed a rapid and convenient assay for measurement of the action of endothelin (ET) converting enzyme (ECE) using the scintillation proximity assay (SPA) principle. On incubation of [125I]big ET-1 at 37 degrees C for 0.5-6 hr with an enzyme preparation, the reaction was terminated by the addition of an ET-1-specific antibody formulated in a buffer designed to shift the pH to alkaline. The antibody was allowed to come to equilibrium for 1 hr at room temperature and the amount of ET-1 produced, detected in a single step by the addition of protein A SPA beads. Using this assay, ECE activities of enzyme preparations obtained from porcine cultured endothelial cells and rat lung were clearly detected. These activities were inhibited by phosphoramidon in a concentration-dependent manner. The SPA based assay is homogeneous requiring no separation steps and takes a half day to complete. This method is therefore suitable for the high throughput screening of potential ECE inhibitors.     

Endothelin-1 in hypertension in the baroreflex-intact SHR: a role independent from vasopressin release

This study sought to identify whether central endothelin (ET) receptor activation contributes to the elevated pressure in spontaneously hypertensive rats (SHR) and whether an ET-stimulated vasopressin (AVP) release mediates the increased pressure. In Wistar Kyoto (WKY) rats, intracerebroventricular ET-1 induced a dose-dependent pressor response that was shifted rightward in SHR. ET(A) antagonism decreased mean arterial pressure in baroreflex-intact SHR (P<0.01), consistent with inhibition of endogenous ET-1, and blocked the pressor response to exogenous ET-1 in both strains. ET-1 increased AVP only after sinoaortic denervation (P<0.05). Contrary to WKY, sinoaortic denervation was required to elicit a significant pressor response with 5 pmol ET-1 in SHR. Sinoaortic denervation permitted ET-1 to increase AVP in both strains, and peripheral V(1) blockade decreased pressure in denervated but not intact rats. After nitroprusside normalized pressure in SHR, the pressor and AVP secretory responses paralleled those in WKY. Thus endogenous ET(A) receptor mechanisms contribute to hypertension, independent of AVP, in baroreflex-intact SHR. Although blunted in the hypertensive state, the arterial baroreflex buffers the ET-1-induced pressor and AVP secretory responses in both strains.     

Inhibition of biological actions of big endothelin-1 by phosphoramidon

Endothelin (ET)-1 and big ET-1 both caused contraction of isolated porcine coronary arteries, but the potency of big ET-1 was 1/100-1/200 that of ET-1. These responses were independent of the vascular endothelium. Phosphoramidon blocked the vasoconstriction caused by 30 nM big ET-1, but was ineffective on the action of 0.3 nM ET-1. Also in vivo, phosphoramidon had no effect on the ET-1-induced pressor actions, but blocked the pressor and airway-contractile responses to big ET-1 in rats and/or guinea pigs. Thus, it is likely that the vascular responses to exogenous big ET-1 are at least in part due to its conversion to ET-1 by a phosphoramidon-sensitive ET converting enzyme(s) in the vascular smooth muscle in vitro and in vivo.     

The endothelin system in human and monkey ovaries: in situ gene expression of the different components

The endothelin system is composed of three endothelin isoforms (ET-1, ET-2, and ET-3), the endothelin receptors ETA and ETB, and the endothelin-converting enzyme (ECE). Besides having a major vasoactive role, endothelins have roles in different cell types at a local level. We investigated the presence of the different components of the endothelin system in primate ovaries. Human ovaries and gonadotropin-stimulated monkey ovaries were studied using immunohistochemistry for endothelin, and in situ hybridization with probes for ET-1, ET-2, ET-3, ETA and ETB receptors, and ECE. ET-1 and ETA receptors were detected in endothelial cells and vascular smooth muscle cells, respectively, in stromal vessels adjacent to follicles and corpora lutea. ETB receptors and ET-1 were found in the endothelial cells of capillaries of corpora lutea. ECE was present in internal theca cells of secondary, de Graaf, atretic follicles, and in luteinized granulosa cells of the corpora lutea. The endothelin system components are present in or around the follicles of human and monkey ovaries. Although the components are not expressed in the same cell types, they are synthesized, mainly in follicles, by cells that are in close proximity. Thus, the endothelin system could act in a paracrine manner. ECE expression in steroid-producing cells changes its compartmentalization during follicle maturation.     

Role of thromboxane receptor activation in the bronchospastic response to endothelin

The selective TxA2/PGH2 (TP) receptor antagonist, SQ 30,741, was used to test the hypothesis that TP-receptor activation contributes to the reactivity of airways and isolated trachea to endothelin-1 (ET-1). Dose-dependent contractions of guinea pig tracheal strips to ET-1 in vitro were unaffected by either SQ 30,741 (1 microM) or indomethacin (2.8 microM). In contrast, maximal bronchospastic responses (increases in airways resistance and decreases in dynamic lung compliance) of anesthetized guinea pigs to ET-1 (0.5 and 1.5 nmole/kg i.v.) in vivo were blocked greater than 90% by SQ 30,741 (1 mg/kg i.v.). Concurrent increases in arterial blood pressure and decreases in leukocyte counts induced by ET-1 were unaffected by SQ 30,741. In rats, ET-1 (1.5 nmole/kg i.v.) did not affect lung mechanics, but did cause biphasic blood pressure and leukopenia responses which were unaltered by SQ 30,741. These data demonstrate that there is considerable species variability in the bronchospastic response to ET-1, and that in guinea pigs, this response is caused predominantly by the activation of TP-receptors.     

Nonpeptide endothelin receptor antagonists attenuate the pressor effect of diaspirin-crosslinked hemoglobin in rat.

Endothelin 1 (ET-1) is a potent vasoactive and mitogenic peptide that is thought to participate in the hemodynamic effects elicited by drugs that block the biosynthesis and release of endothelium-derived nitric oxide (NO), such as NO synthase inhibitors. Using the nonpeptide endothelin receptor antagonists bosentan and LU-135252, we tested the hypothesis that endothelins contribute to the pressor activity of diaspirin-crosslinked hemoglobin (DCLHb), a hemoglobin-based oxygen carrier, whose pressor activity in mammals is attributed primarily to a scavenging action towards NO. The NO synthase inhibitor nitro-L-arginine methyl ester (L-NAME), ET-1, and noradrenaline (NA) were used as reference drugs. Bosentan markedly reduced the pressor effects elicited by DCLHb, L-NAME, and ET-1, but not those evoked by NA. LU-135252 attenuated the pressor effect elicited by DCLHb and ET-1, but not that produced by L-NAME or NA. The decreases in heart rate associated with the pressor effect of DCLHb and L-NAME were reduced by LU-135252, whereas only those elicited by DCLHb were attenuated by bosentan. In contrast with bosentan, LU-135252 caused a decrease in the baseline blood pressure and heart rate. These results suggest that endothelins may participate in the pressor activity of DCLHb. They suggest also that nonpeptide endothelin receptor antagonists such as bosentan or LU-135252 may be useful to counteract endothelin-mediated undesirable hemodynamic effects of drugs that inhibit the activity of the NO system.     

Pepsin, an aspartic protease, converts porcine big endothelin to 21-residue endothelin

Porcine big endothelin (big ET-39) at 1 nM, a concentration with no influence on contractile activity in isolated rat aorta, induced a slow-onset and sustained contraction by the pre-incubation with pepsin. When the incubation mixture of big ET-39 with pepsin was analyzed by high-performance liquid chromatography on an octadecyl silica column, two major products of pepsin hydrolysis were obtained; their amino acid sequences were identical with those of 21-residue endothelin (ET-21) and a C-terminal peptide of big ET-39, big ET (22-39), respectively. On the other hand, no degradation of ET-21 was observed by pepsin treatment. These results indicate that pepsin specifically cleaves a Trp21-Val22 bond in the big ET-39 molecule, producing ET-21 and big ET (22-39). Thus, the possibility that pepsin-like aspartic protease may participate in the conversion of big ET-39 to ET-21 in vivo warrants further attention.     

Phosphoramidon inhibits the vasoconstrictor effects evoked by big endothelin-1 but not the elevation of plasma endothelin-1 in vivo

Intravenous injections of big endothelin (ET)-1 (700 pmol/kg) in the pig increased arterial plasma levels of ET-1-like immunoreactivity (ET-1-LI) from 11.1 +/- 0.7 pM to 46.3 +/- 6.7 pM in the control situation and from 11.5 +/- 0.4 pM to 58.2 +/- 17 pM in the presence of the neutral endopeptidase inhibitor phosphoramidon (3 mg/kg). Big ET-1 increased splenic vascular resistance by 29% in the control situation. The vasoconstriction evoked by big ET-1 in the spleen was reduced after phosphoramidon treatment whereas the elevation of arterial ET-1-LI was not influenced. Furthermore the splenic vasoconstriction evoked by ET-1 was reduced after phosphoramidon without influencing plasma ET-1-LI. Also in rats the pressor effect of big ET-1 (1 nmol/kg) was inhibited by phosphoramidon (5 mg/kg) whereas the elevation of plasma ET-1 was not influenced. It is concluded that the vasoconstrictor effects of both big ET-1 and ET-1 are inhibited, but the increase in plasma ET-1 is unaffected by phosphoramidon.     

Phosphoramidon inhibits the intracellular conversion of big endothelin-1 to endothelin-1 in cultured endothelial cells

Effects of various protease inhibitors on the conversion of big endothelin (ET)-1 to ET-1 in cultured endothelial cells were analyzed. A metal protease inhibitor, phosphoramidon, decreases the amount of ET-1 and increase that of big ET-1 released. This effect is dose-dependent and not nonspecific. When the contents of ET-1 and big ET-1 in the cells after culturing in the medium with or without phosphoramidon were measured, the ratio of ET-1: big ET-1 in the cells was 3.3 : 1 and phosphoramidon inverted the ratio in the cells to 1 : 3.5. These data strongly suggest that a phosphoramidon-sensitive protease converts big ET-1 to mature ET-1 intracellularly.     

Secretion of endothelin-1 in human endothelial cell line but not in B cell line by transfection of preproendothelin-1 cDNA.

Stable transformants with preproendothelin-1 (preproET-1) cDNA were established for the study of the regulation of endothelin-1 (ET-1) biosynthesis in human cells. ET-1, a potent vasoconstrictor peptide, is produced by endothelial cells and is secreted into the blood at a low level. Human preproET-1 cDNA was introduced into two immortal human cell lines, t-HUE2, an endothelial cell line, and Raji, a B cell line, with Ecogpt selection. Several stable transformants of t-HUE2 expressed extraordinarily high levels of preproET-1 specific mRNA and secreted ET-1 into serum-free culture medium, while the transformants of Raji cells expressed high levels of ET-1 mRNA, but secreted a negligible amount of ET-1. Immunocytochemical studies of intracellular ET-1 content revealed that there were some defects in the translation or processing of preproET-1 in the B cell line transformants. In addition, the ratio of ET-1 to ET-1 precursor (big ET-1) was much higher in the t-HUE2 transformants than in normal endothelial cells, suggesting that t-HUE2 transformants (for example t-HUE2-1) possess high levels of endothelin converting enzyme (ECE). The establishment of stable transformants producing high levels of ET-1 in serum-free medium will be useful for the study of cell-type-specific translation and processing to mature ET-1, and of the regulatory factors of ECE.     

Synthesis and degradation of endothelin-1

The endothelin-converting enzyme (ECE) is the main enzyme responsible for the genesis of the potent pressor peptide endothelin-1 (ET-1). It is suggested that the ECE is pivotal in the genesis of ET-1, considering that the knockout of both genes generates the same lethal developments during the embryonic stage. Several isoforms of the ECE have been disclosed, namely ECE-1, ECE-2, and ECE-3. Within each of the first two groups, several sub-isoforms derived through splicing of single genes have also been identified. In this review, the characteristics of each sub-isoform for ECE-1 and 2 will be discussed. It is important to mention that the ECE is, however, not the sole enzyme involved in the genesis of endothelins. Indeed, other moieties, such as chymase and matrix metalloproteinase II, have been suggested to be involved in the production of ET intermediates, such as ET-1 (1-31) and ET-1 (1-32), respectively. Other enzymes, such as the neutral endopeptidase 24-11, is curiously not only involved in the degradation and inactivation of ET-1, but is also responsible for the final production of the peptide via the hydrolysis of ET-1 (1-31). In this review, we will attempt to summarize, through the above-mentioned characteristics, the current wisdom on the role of these different enzymes in the genesis and termination of effect of the most potent pressor peptide reported to date.