Conversion of Big Endothelin-1 and Characterization of Its Contractile Effects on Isolated Human Placental Arteries

Hanson, G. C.; Wide-Swenson, D.; Andersson, Karl-Erik; Lindberg, Bengt

doi:10.1159/000009913

Cited by 4 publications

(3 citation statements)

References 27 publications

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“…Interestingly, the onset of contraction and the increase in tone are slow upon application of big ET-1 when compared to ET-1. This observation suggests the involvement of an enzymemediated step in the contractile action of exogenously applied big ET-1 as previously observed in other vascular tissues such as the rabbit aorta [16] , the human umbilical vein [17] , the human placental artery [18] and the rat basilar artery [15] . Additionally, our results show that phosphoramidon, a non-selective inhibitor of ECE and neutral endopeptidase, produces rightward displacements of the big ET-1 concentration-response curves with a reduction in the maximal response, further indicating that this peptide must be converted to exert its biological activity.…”

Section: Synthesis and Expression Of Et In The Rat Carotidsupporting

confidence: 83%

Mechanisms Underlying the Vascular Actions of Endothelin 1, Angiotensin II and Bradykinin in the Rat Carotid

Tirapelli¹,

Bonaventura²,

Tirapelli³

et al. 2009

Pharmacology

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The carotid artery has a pivotal role in the body since it supplies the head and neck with oxygenated blood. Alterations in the functional and structural integrity of these vessels can decrease blood flow to the brain. For this reason, it is important to understand how the carotid artery responds to various stimuli. The organ bath is a traditional experimental set-up that has been used extensively to investigate the (patho)physiology and pharmacology of in vitro tissue preparations including the rat carotid artery. Molecular biology developed from related fields such as biochemistry, genetics and biophysics is now considered an important tool for understanding physiological pathways in a variety of tissues. Several local and systemic factors regulate carotid reactivity, including vaso-active peptides, such as endothelin 1 (ET-1), angiotensin II (Ang II) and bradykinin (BK). These vaso-active peptides play a fundamental role in controlling the functional and structural integrity of the arterial wall and may be important in physiological processes and in pathological mechanisms underlying vascular diseases. In the rat carotid, these peptides induce vasoconstriction or relaxation by the release of endothelium-derived relaxing factors, such as nitric oxide and prostacyclin. Identification of such signal transduction processes is essential for understanding the mechanisms that regulate vascular smooth muscle cell function, both physiologically and pathophysiologically. The present review discusses the mechanisms of action, distribution of ET-1, Ang II and BK and their receptors in the rat carotid. With this purpose, data obtained in functional studies using classical pharmacological approaches as well as data obtained in molecular biology experiments are discussed.

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Section: Synthesis and Expression Of Et In The Rat Carotidsupporting

confidence: 83%

Mechanisms Underlying the Vascular Actions of Endothelin 1, Angiotensin II and Bradykinin in the Rat Carotid

Tirapelli¹,

Bonaventura²,

Tirapelli³

et al. 2009

Pharmacology

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“…It is well established that BigET‐1 must be converted to ET‐1 to exert its biological activity. Accordingly, phosphoramidon, a nonselective ECE/NEP inhibitor, reduces the contraction induced by BigET‐1 in several vascular tissues (Maguire et al ., 1997; Hanson et al ., 1998) as well as the levels of mature ET‐1 in the bathing medium after addition of the 38 amino acids precursor (Maguire et al ., 1997). Our results show that phosphoramidon produced rightward displacements of the BigET‐1 concentration–response curves with reduction of the maximal response, further indicating that this peptide must be converted to exert its biological activity.…”

Section: Discussionmentioning

confidence: 99%

“…Notwithstanding the above‐mentioned observations, which organs/tissues are predominantly implicated in the generation of ET‐1(1–31) from exogenous BigET‐1 in the rabbit (or in any other species for that matter) still remains to be elucidated. Functional experiments in a variety of vascular tissues, such as the human umbilical vein (Maguire et al ., 1997), the human placental artery (Hanson et al ., 1998) and the rat basilar artery (Zimmermann et al ., 2002), previously showed that the contraction induced by BigET‐1 was sensitive to phosphoramidon, thus supporting a role for the vascular system in the generation of ET peptides. Interestingly, a similar role for chymase has been proposed in the processing of angiotensin I to angiotensin II in the rabbit aorta (Akasu et al ., 1998).…”

Section: Introductionmentioning

confidence: 99%

Enzymatic pathways involved in the generation of endothelin‐1(1–31) from exogenous big endothelin‐1 in the rabbit aorta

Tirapelli¹,

Fecteau²,

Honoré³

et al. 2006

British J Pharmacology

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1 We investigated whether blood vessels contribute to the production of ET-1(1-31) from exogenous big endothelin-1 (BigET-1) in the rabbit and assessed which enzymes are involved in this process. 2 Vascular reactivity experiments, using standard muscle bath procedures, showed that BigET-1 induces contraction in endothelium-intact rabbit aortic rings. Preincubation of the rings with phosphoramidon, CGS35066 or thiorphan reduced BigET-1-induced contraction. Conversely, chymostatin did not affect BigET-1-induced contraction. 3 Thiorphan and phosphoramidon, but not CGS35066 or chymostatin, reduced ET-1(1-31)-induced contraction. None of the enzymatic inhibitors affected the contraction afforded by ET-1. 4 BQ123-, but not BQ788-, selective antagonists for ET A and ET B receptors, respectively, produced concentration-dependent rightward displacements of the ET-1(1-31) and ET-1 concentrationresponse curves. 5 By the use of enzymatic assays, we found that the aorta, as well as the heart, lung, kidney and liver, possess a chymase-like activity. 6 Enzyme immunoassays detected significant levels of Ir-ET-1(1-31) in bathing medium of aortas after the addition of BigET-1 (30 nM). Neither thiorphan nor chymostatin altered the levels of Ir-ET-1(1-31). Conversely, the levels of Ir-ET-1(1-31) were increased in the presence of phosphoramidon. This marked increase of the 31-amino-acid peptide was abolished when phosphoramidon and chymostatin were added simultaneously. 7 The major new finding of the present work is that the rabbit aorta generates ET-1(1-31) from exogenously administered BigET-1. Additionally, by measuring the production of ET-1(1-31), we showed that a chymase-like enzyme is involved in this process when ECE and NEP are inhibited by phosphoramidon. Our results also suggest that ET-1(1-31) is an alternate intermediate in the production of ET-1 following BigET-1 administration. Finally, we showed that NEP is the predominant enzymatic pathway involved in the cleavage of ET-1(1-31) to a bioactive metabolite that will act on ET A receptors to induce contraction in the rabbit aorta.

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Effect of chronic ethanol consumption on endothelin-1 generation and conversion of exogenous big-endothelin-1 by the rat carotid artery

Tirapelli

Casolari

Yogi

et al. 2007

Alcohol

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Conversion of Big Endothelin-1 and Characterization of Its Contractile Effects on Isolated Human Placental Arteries

Cited by 4 publications

References 27 publications

Mechanisms Underlying the Vascular Actions of Endothelin 1, Angiotensin II and Bradykinin in the Rat Carotid

Mechanisms Underlying the Vascular Actions of Endothelin 1, Angiotensin II and Bradykinin in the Rat Carotid

Enzymatic pathways involved in the generation of endothelin‐1(1–31) from exogenous big endothelin‐1 in the rabbit aorta

Effect of chronic ethanol consumption on endothelin-1 generation and conversion of exogenous big-endothelin-1 by the rat carotid artery

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