Disney O. Sivieri scite author profile

Disney O. Sivieri

3Publications

41Citation Statements Received

129Citation Statements Given

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Role of Elastase-2 as an Angiotensin II-Forming Enzyme in Rat Carotid Artery

Becari

Sivieri²,

Santos³

et al. 2005

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We have described the biochemical, enzymatic, and structural properties of a chymostatin-sensitive angiotensin (Ang) I-converting elastase-2 found in the rat mesenteric arterial bed perfusate. We determined the mRNA for elastase-2 and its relative role in generating Ang II in the rat isolated aorta and carotid artery rings. In carotid rings, the Ang I-induced vasoconstrictor effect was only partially inhibited by captopril or chymostatin, whereas that of tetradecapeptide renin substrate (TDP) was greatly inhibited by chymostatin but unaffected by captopril; however, Ang I- and TDP-induced effects were abolished by the combination of both inhibitors. Effects of [Pro11-D-Ala12]-Ang I (PDA), an Ang I-converting enzyme (ACE)-resistant biologically inactive precursor of Ang II were blocked by chymostatin or N-acetyl-Ala-Ala-Pro-Leu-chloromethylketone (elastase-2 inhibitor) in carotid artery. PDA failed to induce an effect in aortic rings, and Ang I-induced contractions were completely inhibited by captopril. The mRNA for rat elastase-2 was detected in aorta, carotid, and mesenteric arteries, although its expression was found to be less important in aorta. These findings indicate the presence of a functional alternative pathway to ACE for Ang II generation in rat carotid artery and represent strong evidence of a physiological role for elastase-2; however, its functional contribution to Ang II formation in aorta appears to be negligible.

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Potentiation of Bradykinin Effect by Angiotensin-Converting Enzyme Inhibition Does Not Correlate With Angiotensin-Converting Enzyme Activity in the Rat Mesenteric Arteries

Sivieri¹,

Bispo-da-Silva

Oliveira

et al. 2007

Hypertension

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Abstract-Angiotensin-converting enzyme (kininase II [ACE]) inhibitors are capable of potentiating bradykinin (BK) effects by enhancing the actions of bradykinin on B 2 receptors independent of blocking its inactivation. To investigate further the importance of ACE kininase activity on BK-induced vasodilation, we investigated the effect of inhibiting ACE, as well as other kininases, on both BK metabolism and vasodilator effect in preparations that exhibit increased ACE activity. Mesenteric arterial beds obtained from 1-kidney, 1-clip hypertensive rats presented augmented ACE and angiotensin I converting activities compared with normotensive rats. The isolated and perfused mesenteric beds were exposed to BK for 15 minutes in the absence or in the presence of kininase inhibitors; then, the perfusate was collected for analysis of the products of BK metabolism by high-performance liquid chromatography. BK was metabolized to the fragments BK(1-8), BK(1-7), and BK(1-5), and the recovery of intact BK was reduced by 47% in the hypertensive group. Recovery of BK was increased in both groups in the presence of a kininase I inhibitor and in the hypertensive group by neutral endopeptidase 24.11 inhibitor; however, ACE inhibition did not affect BK metabolism in both groups. In contrast, only the ACE inhibitor potentiated the vasodilator effect of BK in a mesenteric bed preconstricted with phenylephrine; the increase in BK effect, nevertheless, was not greater in arteries from hypertensive rats that presented an increased ACE activity when compared with those in the normotensive group. These data demonstrated that ACE inhibitor-induced potentiation of BK vasodilator effects is not related to their actions on BK degradation. Key Words: bradykinin Ⅲ ACE activity Ⅲ kininase I Ⅲ endopeptidases Ⅲ ACE inhibitor T he nonapeptide bradykinin (BK) has important pharmacological effects on blood vessels, heart, and kidney; among these, the most conspicuous is the transient hypotensive effect when BK is administered into the systemic circulation in all of the species studied. 1 This effect results from resistance vessel dilation in several beds mediated by the release of endothelial relaxing factors after the activation of B 2 receptors. 2,3 The remarkably short half-life of BK in vivo has been attributed to the rapid enzymatic degradation by several peptidases (collectively known as "kininases") present in plasma and tissues. The role that a particular kininase plays in the metabolism of BK depends on its localization and the presence of other peptidases in plasma or tissue. The predominant kininases that degrade BK in most tissues are the metallopeptidases kininase II (angiotensinconverting enzyme [ACE]), kininase I (carboxypeptidase M and N), and neutral endopeptidase 24.11 (NEP). 4 -7 ACE is primarily a surface enzyme that removes the C-terminal dipeptide from BK, which leads to its complete inactivation. ACE eventually cleaves further its primary metabolite, BK(1-7), into the shorter fragment, BK(1-5). NEP, another membrane-bound pe...

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Carboxypeptidase B and other kininases of the rat coronary and mesenteric arterial bed perfusates

Oliveira¹,

Souza²,

Sivieri³

et al. 2007

American Journal of Physiology-Heart and Circulatory Physiology

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We describe the enzymes that constitute the major bradykinin (BK)-processing pathways in the perfusates of mesenteric arterial bed (MAB) and coronary vessels isolated from Wistar normotensive rats (WNR) and spontaneously hypertensive rats. The contribution of particular proteases to BK degradation was revealed by the combined analysis of fragments generated during incubation of BK with representative perfusate samples and the effect of selective inhibitors on the respective reactions. Marked differences were seen among the perfusates studied; MAB secretes, per minute of perfusion, kininase activity capable of hydrolyzing approximately 300 pmol of BK/min, which is approximately 250-fold larger amount on a per unit time basis than that of its coronary counterpart. BK degradation in the coronary perfusate seems to be mediated by ANG I-converting enzyme, neutral endopeptidase 24.11-like enzyme, and a dl-2-mercaptomethyl-3-guanidinoethylthiopropanoic acid-sensitive basic carboxypeptidase; coronary perfusate of WNR contains an additional BK-degrading enzyme whose specificity resembles that of neurolysin or thimet oligopeptidase. Diversely, a des-Arg(9)-BK-forming enzyme, responsible for nearly all of the kininase activity of MAB perfusates of WNR and spontaneously hypertensive rats, could be purified by a procedure that involved affinity chromatography over potato carboxypeptidase inhibitor-Sepharose column and shown to be structurally identical to rat pancreatic carboxypeptidase B (CPB). Comparable levels of CPB mRNA expression were observed in pancreas, liver, mesentery, and kidney, but very low levels were detected in lung, heart, aorta, and carotid artery. In conclusion, distinct BK-processing pathways operate in the perfusates of rat MAB and coronary bed, with a substantial participation of a des-Arg(9)-BK-forming enzyme identical to pancreatic CPB.

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Disney O. Sivieri

Role of Elastase-2 as an Angiotensin II-Forming Enzyme in Rat Carotid Artery

Potentiation of Bradykinin Effect by Angiotensin-Converting Enzyme Inhibition Does Not Correlate With Angiotensin-Converting Enzyme Activity in the Rat Mesenteric Arteries

Carboxypeptidase B and other kininases of the rat coronary and mesenteric arterial bed perfusates

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