The peptidase inhibitor CGS-26303 increases endothelin converting enzyme-1 expression in endothelial cells through accumulation of big endothelin-1

Hyperphosphatemia induces senescence in human endothelial cells by increasing endothelin-1 production

Hyperphosphatemia is related to some pathologies, affecting vascular cell behavior. This work analyzes whether high concentration of extracellular phosphate induces endothelial senescence through up‐regulation of endothelin‐1 (ET‐1), exploring the mechanisms involved. The phosphate donor β‐glycerophosphate (BGP) in human endothelial cells increased ET‐1 production, endothelin‐converting enzyme‐1 (ECE‐1) protein, and mRNA expression, which depend on the AP‐1 activation through ROS production. In parallel, BGP also induced endothelial senescence by increasing p16 expression and the senescence‐associated β‐galactosidase (SA‐ß‐GAL) activity. ET‐1 itself was able to induce endothelial senescence, increasing p16 expression and SA‐ß‐GAL activity. In addition, senescence induced by BGP was blocked when different ET‐1 system antagonists were used. BGP increased ROS production at short times, and the presence of antioxidants prevented the effect of BGP on AP1 activation, ECE‐1 expression, and endothelial senescence. These findings were confirmed in vivo with two animal models in which phosphate serum levels were increased: seven/eight nephrectomized rats as chronic kidney disease models fed on a high phosphate diet and aged mice. Both models showed hyperphosphatemia, higher levels of ET‐1, and up‐regulation in aortic ECE‐1, suggesting a direct relationship between hyperphosphatemia and ET‐1. Present results point to a new and relevant role of hyperphosphatemia on the regulation of ET‐1 system and senescence induction at endothelial level, both in endothelial cells and aorta from two animal models. The mechanism involved showed a higher ROS production, which probably activates AP‐1 transcription factor and, as a result, ECE‐1 expression, increasing ET‐1 synthesis, which in consequence induces endothelial senescence.

Nitric oxide decreases the expression of endothelin-converting enzyme-1 through mRNA destabilization

OBJECTIVE

Endothelial function depends on the equilibrium in the synthesis of vasoactive endothelial factors. It is well known that endothelin and nitric oxide (NO) exhibit reciprocal regulation. We assessed the ability of NO to regulate endothelin-converting enzyme-1 (ECE-1) expression in vascular endothelial cells.

METHODS AND RESULTS

Bovine aortic endothelial cells were incubated with 2 different NO donors as well as with a cyclic-GMP analog, dibutyryl-cGMP (dB-cGMP). ECE-1 protein content and mRNA expression were evaluated by Western blot and Northern blot, respectively, promoter activity by transfection experiments, ECE-1 activity by ELISA, and cGMP production by radioimmunoassay. Both NO donors decreased ECE-1 protein content, mRNA expression, and ECE-1 activity. ODQ, an inhibitor of soluble guanylyl cyclase, blocked those effects. NO donors raised cGMP levels, and dB-cGMP mimicked their effects on ECE-1 expression, which were blocked by KT5823, a nonspecific PKG inhibitor. The changes on ECE-1 expression were due to a destabilization on 3'-untranslated region (3'-UTR) of this mRNA, because the activity of a luciferase reporter construct containing the 3'-UTR of the ECE-1 gene was reduced by dB-cGMP in a PKG-dependent manner. The biological relevance of this regulation was confirmed in bovine aortic endothelial cells coincubated with macrophages in the presence of lipopolysaccharide, in eNOS-deficient mice, and in Wistar rats treated with NO donors. In every case, an inverse relationship was observed between NO and ECE-1 protein content.

CONCLUSION

Our results support that NO regulates ECE-1 expression through a cGMP/PKG-dependent regulatory mechanism at the post-transcriptional level via the 3'-UTR of the ECE-1 gene.

The impact of the endothelin type A receptor on regional endothelin-1 turnover, in particular renal endothelin-1 release, in humans

The endothelin type A (ETA) receptor was studied in six healthy subjects on two occasions with or without an ETA receptor (BQ-123) blockade. At 40 min of either BQ-123 or NaCl infusion, a concomitant infusion of the endothelin-1 (ET-1) precursor, big ET-1, was initiated to augment ET-1 formation. Blood samples were taken from catheters in a peripheral artery, the renal and femoral veins, and the pulmonary artery. Forty minutes of infusion with BQ-123 alone increased heart rate (P<0.001) and cardiac output (CO; P<0.01) and depressed mean arterial blood pressure (P<0.001) and systemic vascular resistance (SVR; P<0.01). During infusion of big ET-1 alone, CO, stroke volume, and renal blood flow decreased (P<0.01), whereas SVR and pulmonary and renal vascular resistance increased (P<0.05). These responses to big ET-1 were abolished or diminished by BQ-123. Renal ET-1 release was threefold higher when big ET-1 infusion was preceded by BQ-123 infusion (P<0.001). Arterial ET-1 concentrations rose to similar levels after big ET-1 infusion (P<0.01) in both trials because of elevated concomitant pulmonary uptake (P<0.05) after ETA blockade. Although there was no net ET-1 leg exchange, leg ET-1 turnover was higher after big ET-1 was preceded by BQ-123. Gene expression of endothelin-converting enzyme 1 and ET-1 in skeletal muscle remained unaltered on both occasions. Our data demonstrate that the level of circulating ET-1 is regulated by ETA receptor-mediated negative feedback. This mechanism seems to be coupled to increased conversion of big ET-1 and is most potent in the kidneys. This emphasizes the important physiological role of ETA receptors in the kidneys, and the lung seems to be mainly a clearing organ for ET-1.

Targeting the endothelin system: novel therapeutic options in gynecological, urological and breast cancers

The endothelin system comprises the three peptide hormones endothelin (ET)-1, -2, -3, their G protein-coupled receptors, endothelin-A-receptor (ET(A)R) and endothelin-B-receptor (ET(B)R), and the enzymes of endothelin biosynthesis and degradation. In the past two decades, an impressive amount of data has been accumulated investigating the role of the endothelin system in a variety of malignancies. In many cancers, ET-1/ET(A)R interaction induces proliferation, angiogenesis, antiapoptosis and resistance to chemotherapy. Data indicate a pivotal role of the endothelin system in tumorigenesis, local progression and metastasis. Subsequently, novel drugs have been designed inhibiting ET-1 biosynthesis or ET(A)R interaction. A wide range of preclinical data is available on the role of ET(A)R antagonists in gynecological, urological and breast cancers providing evidence for their antiangiogenic, proapoptotic and growth inhibitory effects. Of particular interest is the anti-invasive and antimetastatic efficacy of ET(A)R antagonists and synergism when co-administered with established cancer therapies. Data indicate a future role of ET(A)R antagonists in oncologic therapies.