Sylvia Mueller scite author profile

Synthetic analogues of the bradykinin potentiating nonapeptide BPP9alpha indicate significantly different structural requirements for potentiation of the bradykinin (BK)-induced smooth muscle contraction (GPI) and the inhibition of isolated somatic angiotensin I-converting enzyme (ACE). The results disprove the ACE inhibition as the only single mechanism and also the direct interaction of potentiating peptides with the bradykinin receptors in transfected COS-7 cells as molecular mechanism of potentiation. Our results indicate a stimulation of inositol phosphates (IPn) formation independently from the B2 receptor. Furthermore, the results with La3+ support the role of extracellular Ca2+ and its influx through corresponding channels. The missing effect of calyculin on the GPI disproves the role of phosphatases in the potentiating action. These experimental studies should not only contribute to a better understanding of the potentiating mechanisms but also incorporate a shift in the research towards the immune system, in particular towards the immunocompetent polymorphonuclear leukocytes. The chemotaxis of these cells can be potentiated most likely by exclusive inhibition of the enzymatic degradation of bradykinin. Thus the obtained results give evidence that the potentiation of the bradykinin action can occur by different mechanisms, depending on the system and on the applied potentiating factor.

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Differential Regulation of Peptide α-Amidation by Dexamethasone and Disulfiram

Driscoll

Mueller²,

Eipper³

et al. 1999

Mol Pharmacol

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alpha-Amidation is essential for the function of many peptides in intercellular communication. This C-terminal modification is mediated in a two-step process by the hydroxylase and lyase activities of the bifunctional enzyme, peptidylglycine alpha-amidating monooxygenase (PAM). The first step, catalyzed by peptidylglycine-alpha-hydroxylating monooxygenase (PHM; EC 1.14.17. 3), is rate limiting in the process, and therefore subject to regulation. Dexamethasone and disulfiram (tetraethylthiuram disulfide; Antabuse) were used as in vivo treatments to study the regulation of PHM expression and activity in cardiac atrium. Our findings show that both dexamethasone and disulfiram treatment increase the activity of PHM in atrial tissue but that they do so by distinctly different mechanisms. Dexamethasone elevated tissue levels of PAM mRNA and protein concurrently, suggesting that glucocorticoids regulate PAM expression at the level of gene transcription. In contrast, disulfiram treatment, which depletes stores of alpha-amidated peptides, increased the specific activity of PHM without affecting the level of PAM expression. The catalytic efficiency of PHM was enhanced by raising the Vmax of the enzyme. Importantly, this increase in Vmax was retained through purification to homogeneity, indicating that either a covalent modification or a stable conformational change had occurred in the protein. These novel findings demonstrate that the rate-limiting enzyme in the bioactivation of peptide messengers is differentially regulated by transcriptional and post-transcriptional mechanisms in vivo. It is proposed that regulation of PHM's expression and catalytic efficiency serve as coordinated physiologic mechanisms for maintaining appropriate levels of alpha-amidating activity under changing conditions in vivo.

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Hypothesized and found mechanisms for potentiation of bradykinin actions

Mueller

Paegelow

Reißmann³

2006

Signal Transduction

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Potentiation of hormone actions can occur by different mechanisms, including inhibition of degrading enzymes, interaction with the hormone receptor leading to stabilization of bioactive conformation or leading to receptor homo-and hetero-oligomerization, receptor phosphorylation and dephosphorylation or can occur by directly influencing the signal transduction and ion channels. In this review the potentiation of bradykinin actions in different systems by certain compounds will be reviewed. Despite many long years of experimental research and investigation the mechanisms of potentiating action remain not fully understood. One of the most contradictory findings are the distinct differences between the inhibition of the angiotensin I-converting enzyme and the potentiation of the bradykinin induced smooth muscle reaction. Contradictory findings and hypothesized mechanisms in the literature are discussed in this review and in some cases compared to own results. Investigation of potentiating actions was extended from hypotension, smooth muscle reaction and cellular actions to activation of immunocompetent cells. In our opinion the potentiation of bradykinin action can occur by different mechanisms, depending on the system and the applied potentiating factor used.Hormone actions can be potentiated by different factors interacting with the receptor, by enzymatic degradation or by signal pathways. However the entire overall process has been studied in detail for only very few hormones [1][2][3]. For therapeutically used hormones this knowledge about potentiating compounds and their action mechan-

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Captopril Inhibits Peptidylglycine- α-Hydroxylating Monooxygenase: Implications for Therapeutic Effects

Mueller¹,

Driscoll²,

Mueller³

1999

Pharmacology

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The therapeutic actions of captopril are facilitated by its sulfhydryl moiety which interacts with the metal (Zn²⁺) prosthetic groups of angiotensin-converting enzyme (ACE; EC 3.4.15.1). This study focused on captopril as an inhibitor of another metal-dependent (Cu²⁺) enzyme, peptidylglycine-α-hydroxylating monooxygenase (PHM; EC 1.14.17.3). PHM is rate limiting in α-amidation, a COOH-terminal modification that bioactivates several pressor peptides. Captopril inhibited PHM in vitro in a dose-dependent manner with an IC₅₀ of approximately 100 μmol/l. This inhibition was partially reversed by increased concentrations of Cu²⁺. Structurally similar nonsulfhydryl ACE inhibitors did not affect the activity of PHM. The present findings indicate that the therapeutic effectiveness of captopril may result from actions on a range of metalloenzymes including ACE and PHM.

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Intramolecular signal transduction by the bradykinin B2 receptor

Mueller

Liebmann

Reißmann

2002

International Immunopharmacology

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Sylvia Mueller

Potentiation of bradykinin actions by analogues of the bradykinin potentiating nonapeptide BPP9α

Differential Regulation of Peptide α-Amidation by Dexamethasone and Disulfiram

Hypothesized and found mechanisms for potentiation of bradykinin actions

Captopril Inhibits Peptidylglycine- α-Hydroxylating Monooxygenase: Implications for Therapeutic Effects

Intramolecular signal transduction by the bradykinin B2 receptor

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