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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Pharmacological Modulation of Mucosa-Related Impairment of β-Adrenoceptor-Mediated Relaxation in Human Detrusor

Propping, Stefan, Roedel, Melanie, Wirth, Manfred P., Ravens, Ursula 14 November 2023 (has links)
Objectives: The mucosa of human detrusor strips impairs catecholamine-induced relaxation. In order to elucidate which signal transduction pathways are involved in this cross talk between the mucosa and detrusor, we have studied the effects of several pharmacological agonists and antagonists on noradrenaline-mediated relaxation in intact and mucosa-denuded detrusor strips. Patients and Methods: Strips of detrusor tissue were obtained from patients who had undergone cystectomy for bladder cancer and were set up for force measurement. KCl- or carbachol-precontracted strips were relaxed with increasing concentrations of noradrenaline in the absence and in the presence of nitric oxide synthase inhibitor, L-NAME; P2X-receptor antagonist, PPADS; ET A -receptor antagonist, BQ-123; ET B -receptor antagonist, BQ-788; cyclooxygenase inhibitor, diclofenac; AT 1 -receptor antagonist, candesartan; and NK 1 -receptor antagonist, L-703,606. Results: In intact strips, KCl-stimulated force was enhanced by all blockers; carbachol-stimulated force increased with L-703,606. In denuded strips, only L-NAME augmented the KCl-stimulated contraction. Noradrenaline relaxed the precontracted detrusor strips to a significantly larger extent and at lower concentrations in denuded than in intact strips. L-NAME, PPADS and BQ-123/BQ-788 had little effect on noradrenaline-induced relaxation, whereas diclofenac, candesartan and L-703,606 sensitized intact carbachol-stimulated detrusor strips to noradrenaline-induced relaxation. Conclusion: Inhibition of the noradrenaline-induced relaxation of precontracted human detrusor strips by the mucosa is attenuated by diclofenac, candesartan and L-703,606 suggesting the involvement of prostanoids, angiotensin and neurokinin pathways. Further experiments are required to unravel the exact mechanisms.
2

Analyse der Funktion der nichtmuskulären schweren Myosinketten in glatten Muskelzellen

Zepter, Valeria Lamounier 13 January 2003 (has links)
Das Ziel dieser Studie war es, die Beteiligung der nichtmuskulären schweren Myosinketten an der Kontraktion der glatten Muskeln unter physiologischen Bedingungen zu untersuchen. Als Versuchsmodell wurde die Harnblase von neugeborenen Wildtyp und transgenen Mäusen verwendet, bei denen das Gen für die glattmuskelspezifischen schweren Myosinketten durch "Gene Targeting" funktionell eliminiert wurde (Knock-Out). Das Fehlen der Expression der glattmuskelspezifischen schweren Myosinketten wurde durch Elektrophorese und Immunfärbung bestätigt. Im Gegensatz dazu blieb die Expression der nichtmuskulären schweren Myosinketten unverändert. Die mechanische Analyse des glatten Muskels wurde mit intakten Muskelpräparaten aus der Harnblase durchgeführt. Das Muskelpräparat wurde in KCl-Lösung oder mit Phorbolester stimuliert. Die Aktivierung mittels depolarisierender KCl-Lösung führte bei neugeborenen Wildtyp Mäusen zuerst zu einer transienten Kontraktion (Phase 1) mit hoher Kraftentwicklung und maximaler Verkürzungsgeschwindigkeit, und danach zu einer tonischen Kontraktion (Phase 2) mit niedrigerer Kraftentwicklung und maximaler Verkürzungsgeschwindigkeit. Blasenpräparate neugeborener Knock-Out Mäuse dagegen zeigten keine Phase 1, sondern nur eine tonische Kontraktion, die mit Wildtyp Mäusen vergleichbar war. Daher scheint nichtmuskuläres Myosin an der tonischen Kontraktion des glatten Muskels beteiligt zu sein. Durch Stimulierung mit Phorbolester waren ähnliche tonische Muskelkontraktionen der Blasenpräparate sowohl bei Wildtyp als auch bei Knock-Out Mäusen zu beobachten. Vermutlich wird also das nichtmuskuläre Myosin durch Stimulierung mit Phorbolester aktiviert. Intrazelluläre Filamente wurden durch Immunfluoreszenz mit einem spezifischen Antikörper gegen nichtmuskuläre schwere Myosinketten in kultivierten primären glatten Muskelzellen untersucht. Dabei zeigten die Muskelzellen sowohl von Wildtyp als auch von Knock-Out Mäusen intrazelluläre dicke Myosinfilamente, was für die Beteiligung des nichtmuskulären Myosins an der glatten Muskelkontraktion spricht. Entsprechend wurden intrazelluläre Filamente mit einem Antikörper gegen glattmuskelspezifische schwere Myosinketten in kultivierten primären glatten Muskelzellen untersucht. Wie erwartet, konnten nur in glatten Muskelzellen von Wildtyp Mäusen intrazelluläre Filamente nachgewiesen werden, nicht aber in denen von Knock-Out Mäusen. In dieser Arbeit konnte zum ersten Mal gezeigt werden, dass nichtmuskuläres Myosin zumindest an der tonischen Kontraktion glatter Muskelzellen beteiligt sein kann. / The aim of the present study was to investigate the involvement of non-muscle myosin heavy chain in smooth muscle contraction under physiological conditions. As an experimental model urinary bladder from neonatal wild-type mice as well as from neonatal mice with disrupted smooth muscle myosin heavy chain expression was used. This animal model was established through gene targeting technology, resulting in complete elimination of the expression of smooth muscle myosin heavy chains. The lack of expression of smooth muscle myosin heavy chains was confirmed by electrophoresis and immunoblotting. On the other hand, non-muscle myosin heavy chain expression remained normal, as verified by Western blot analysis. The mechanical analysis of smooth muscle was performed with intact urinary bladder preparations, stimulated using prolonged KCl depolarization or with phorbol ester. Prolonged activation by KCl depolarization of intact bladder preparations from wild-type neonatal mice produced an initial transient state (phase 1) of high force generation and maximal shortening velocity, followed by a sustained state (phase 2) with lower force generation and maximal shortening velocity. In contrast, bladder preparations from homozygous knockout neonatal mice did not exhibit phase 1, but phase 2 could be observed, i.e. a similar isometric force and maximal shortening velocity, compared to wild-type phase 2. Thus, non-muscle myosin appears to be recruited in the sustained phase of smooth muscle contraction during prolonged KCl depolarization in the animal model used. Upon stimulation with phorbol ester a similar sustained contraction was observed in both wild-type and knockout smooth muscle preparations. Therefore, non-muscle myosin may also be recruited during phorbol ester stimulation in both wild-type and knockout muscle preparations. The participation of non-muscle myosin in smooth muscle contraction was further supported by the finding of longitudinally arranged intracellular filaments in cultivated smooth muscle cells from both wild-type and knockout mice by immunofluorescence microscopy, using a specific antibody raised against non-muscle myosin heavy chain. In a similar way, smooth muscle myosin heavy chain structures were investigated in cultivated smooth muscle cells. As expected, longitudinally arranged intracellular filamentous structures of smooth muscle myosin were observed in wild-type smooth muscle cells, but not in smooth muscle cells from knockout mice. In conclusion, in neonatal smooth muscle the initial phase of contraction elicited by KCl depolarization is generated by smooth muscle myosin heavy chain recruitment. Upon prolonged KCl depolarization non-muscle myosin is recruited in the sustained phase of contraction, as well as upon stimulation with phorbol ester. Thus, it was possible, for the first time, to verify the involvement of the non-muscle myosin in smooth muscle contraction in vivo. The results of the present study contribute to the understanding of the regulatory mechanisms of smooth muscle contraction.

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