Global ETD Search

21	Posttranslationale Modifikationen der IL-6-Typ-Zytokin-Rezeptoren gp130 und LIFR und ihr Einfluss auf die Assoziation mit Detergenz-resistenten Membranmikrodomänen (DRM) Ziegler, Inna. January 2008 (has links) Hohenheim, Univ., Diss., 2008.
22	Solubilisierung und Charakterisierung der Sialat-4-O-Azetyltransferase aus Golgi-Membranen der Leber des Meerschweinchens Iwersen, Matthias. Unknown Date (has links) (PDF) Universiẗat, Diss., 2000--Kiel.
23	Organization and formation of the apical membrane of epithelial cells / Organisation und Bildung der apikalen Membran von Epithelzellen Meder, Doris 15 November 2004 (has links) (PDF) Compartmentalization of cell membranes, in particular of the apical membrane of columnar epithelia, is the topic of this thesis. The first part characterizes the apical membrane and its specialized organization and morphology, whereas the second part focuses on the formation of this unique plasma membrane domain during epithelial polarization. The apical membrane of columnar epithelia is enriched in glycosphingolipids, a class of lipids that are known to interact with cholesterol to form liquid ordered domains, also termed &quot;rafts&quot;, in cell membranes. Imaging the apical surface of untreated and raft lipid depleted MDCK cells with atomic force microscopy revealed that raft lipids are involved in the formation and/or maintenance of microvilli, actin based protrusions of the apical plasma membrane, indicating a regulatory link between membrane domains and the cytoskeleton. Furthermore, antibody patching and photobleaching experiments performed during the work of this thesis suggest that the organization into raft and non-raft domains is very different in the apical membrane of MDCK cells compared to the plasma membrane of a fibroblast. In fact, the data support the hypothesis that the apical membrane could be a percolating raft membrane in which rafts constitute the major phase and non-raft domains exist as isolated entities. The second part of this thesis analyses the segregation of apical and basolateral membrane domains during epithelial polarization. This segregation can either be achieved by generating scaffolded domains prior to junction formation or by polarized secretory and endocytic membrane traffic after the establishment of cell junctions. While most apical and basolateral marker proteins in MDCK cells follow the latter mechanism, this thesis reports that the apical marker gp135 is confined to the dorsal face already in single attached cells. The unknown antigen was purified and identified as podocalyxin. Analysis of a series of domain mutants revealed that the C-terminal PDZ-binding motif of podocalyxin is mainly responsible for its special localization, which it shares with the PDZ protein NHERF-2. Knocking down podocalyxin by RNA interference resulted in retardation of cell growth and epithelial polarization. Taken together, the data suggest that podocalyxin and NHERF-2 could be part of an early apical polarity scaffolding system based on PDZ-binding and PDZ-containing proteins. AFM Epithelzellen FRAP Lipide Polarität apikal AFM FRAP apical epithelial cells polarity rafts ddc:570 rvk:WE 5000 Biomembran Epithelzelle Fluoreszensanalyse Kompartimentierung Kraftmikroskopie Lipide Polarität
24	Lysosome biogenesis during osteoclastogenesis Apfeldorfer, Coralie 29 November 2006 (has links) (PDF) Lysosomes are acidic, hydrolase-rich vesicles capable of degrading most biological macromolecules. During the past several decades, much has been learned about different aspects of lysosome biogenesis. The selective phosphorylation of mannose residues on lysosomal enzymes, in conjunction with specific receptors for the mannose-6-phosphate recognition marker, has been found to be largely responsible for the targeting of newly synthesized lysosomal enzymes to lyzosomes. It is known that lysosomes receive input from both the endocytotic and biosynthetic pathways. Nevertheless the exact molecular mechanisms responsible for sorting of the biosynthetic imput involved in the lysosome biogenesis is still a matter of debate. Because osteoclast precursors do not secrete their lysosomal enzymes and osteoclasts do, the observation of modifications occuring during osteoclastogenesis is a good model to observe mechanisms responsible for lysosomal enzymes traffic. Osteoclasts are bone-degrading cells. To perform this specific task they have to reorganise the sorting of their lysosomal enzymes to be able to target them toward the bone surface in mature cells. Since few years, the differentiation of osteoclasts in vitro did help to study these cells. Osteoclast morphology has been therefore already well studied, and the nature of their specific membrane domains is now established. Sensing the proximity of a bone-like surface the cell reorganises its cytoskeleton, and creates specific membrane domains: an actin-rich ring-like zone (named actin ring) surrounded by highly ruffled membrane (named the ruffled border) where enzymes are secreted, while subsequent bone degradation products are endocytosed. Endocytosed material is then transported through the cell inside transcytotic vesicles and released at the top of the cell in an area named the functional secretory domain. Several molecular machineries are thought to control these different phenomena. The main purpose of this thesis was to identify the major regulators of lysosomal enzymes secretion and therefore to identify the molecular switches responsible for such a membrane traffic re-organisation. osteoclast lysosome membrane traffic rab endosome Osteoclast Lysosome Membrane traffic Rab Endosome ddc:570 rvk:WD 5275 Osteoklast Lysosom Biomembran Rab-Proteine Endosom
25	Polymorphism of Biomembranes at the Nanoscale Satarifard, Vahid 05 January 2021 (has links) In dieser Arbeit untersuchen wir den Polymorphismus von Biomembranen im Nanometerbereich anhand von Computermodellen. In Kapitel drei werden auf Dissipative Particle Dynamis basierende molekulare Simulationen genutzt, um die Wechselwirkungen zwischen Membranen und Nanotropfen mit hohen Oberflächenspannungen in der Größenordnung von Milli Newton pro Meter zu untersuchen. Wir zeigen, dass Nanotropfen eine negative Linienspannung an der dreiphasigen Kontaktlinie mit der Membran aufweisen. Die negative Linienspannung führt zu einem spontanen Symmetriebruch des Membran-Tropfensystems und zur Bildung eines enggeschlossenen länglichen Membranhalses. In Kapitel vier untersuchen wir Nanotropfen mit niedrigen Grenzflächenspannungen in der Größenordnung von Mikro-Newton pro Meter. Eine Energieminimierung ermöglicht uns, eine Vielzahl von Parametern zu variieren und die Abhängigkeit der Membranbenet-zungsphänomene von der Grenzflächenspannung, der Biegesteifigkeit, der Linienspannung und der spontanen Krümmung systematisch zu bestimmen. Wir beobachten eine neue morphologische Transformation, die sowohl die Vesikel als auch das Tröpfchen betrifft und eine weiter Geometrie mit gebrochener Rotationssymmetrie. Schließlich bestimmen wir die Grenze zwischen symmetrischen und asymmetrischen Kontaktlinien innerhalb des dreidimensionalen Parameterraums bei verschwindender spontanen Krümmung. In Kapitel fünf verwenden wir molekulare Simulationen, um die morphologischen Transformationen einzelner Nanovesikel mit unterschiedlichem Grad an Asymmetrie zwischen den beiden Schichten der Doppelmembranen zu beobachten. Wir beginnen mit kugelförmigen Vesikeln, die ein bestimmtes Wasservolumen einschließen und aus einer bestimmten Gesamtzahl von Lipiden bestehen. Wenn ihr Volumen verringert wird, verwandeln sich die kugelförmigen Vesikel in eine Vielzahl von nicht kugelförmigen Formen. Dieser Polymorphismus kann durch Umverteilung weniger Lipide zwischen der inneren und äußeren Schicht der Membranen kontrolliert werden. / In this thesis, we use computational methods to study polymorphism of biomembranes at the nanoscales. In chapter three, we use molecular simulations based on dissipative particle dynamics to investigate the interaction of membranes with nanodroplets at high interfacial tensions of the order of milli Newton per meter. We find that nanodroplets have negative line tension at the three phase contact line on the membrane. The negative line tension leads to spontaneous symmetry breaking of the membrane-droplet system and formation of a tight-lipped membrane neck. In chapter four, we study nanodroplets with low interfacial tensions of the order of micro Newton per meter. We use energy minimization, which allows us to explore a wide range of parameters and to systemati-cally determine the dependence of membrane wetting phenomena on interfacial tension, bending rigidity, line tension, and spontaneous curvature. We observe a new morphological transformation that involves both vesicles and droplets, leads to another regime with broken rotational symmetry. Finally, we determine the boundary between symmetric and asymmetric contact line geometries within the three-dimensional parameter space in vanishing spontaneous curvature. In chapter five, we use molecular simulations to monitor the morphological transformations of individual nanovesicles with different degrees of asymmetry between the two leaflets of the bilayer membranes. We start with the assembly of spherical vesicles that enclose a certain volume of water and contain a certain total number of lipids. When we reduce their volume, the spherical vesicles transform into a multitude of nonspherical shapes such as oblates and stomatocytes as well as prolates and dumbbells. This polymorphism can be controlled by redistributing a small fraction of lipids between the inner and outer leaflets of the bilayer membranes. As a consequence, the inner and the outer leaflets experience different mechanical tensions. Biomembran Vesikel Nanodroplet Pinocytose Kontaktlinie Schnur Membranhals Biomembrane Vesicle Nanodroplet Pinocytosis Contact line Line tension Membrane neck 530 Physik ddc:530
26	Organization and formation of the apical membrane of epithelial cells Meder, Doris 18 June 2004 (has links) Compartmentalization of cell membranes, in particular of the apical membrane of columnar epithelia, is the topic of this thesis. The first part characterizes the apical membrane and its specialized organization and morphology, whereas the second part focuses on the formation of this unique plasma membrane domain during epithelial polarization. The apical membrane of columnar epithelia is enriched in glycosphingolipids, a class of lipids that are known to interact with cholesterol to form liquid ordered domains, also termed &quot;rafts&quot;, in cell membranes. Imaging the apical surface of untreated and raft lipid depleted MDCK cells with atomic force microscopy revealed that raft lipids are involved in the formation and/or maintenance of microvilli, actin based protrusions of the apical plasma membrane, indicating a regulatory link between membrane domains and the cytoskeleton. Furthermore, antibody patching and photobleaching experiments performed during the work of this thesis suggest that the organization into raft and non-raft domains is very different in the apical membrane of MDCK cells compared to the plasma membrane of a fibroblast. In fact, the data support the hypothesis that the apical membrane could be a percolating raft membrane in which rafts constitute the major phase and non-raft domains exist as isolated entities. The second part of this thesis analyses the segregation of apical and basolateral membrane domains during epithelial polarization. This segregation can either be achieved by generating scaffolded domains prior to junction formation or by polarized secretory and endocytic membrane traffic after the establishment of cell junctions. While most apical and basolateral marker proteins in MDCK cells follow the latter mechanism, this thesis reports that the apical marker gp135 is confined to the dorsal face already in single attached cells. The unknown antigen was purified and identified as podocalyxin. Analysis of a series of domain mutants revealed that the C-terminal PDZ-binding motif of podocalyxin is mainly responsible for its special localization, which it shares with the PDZ protein NHERF-2. Knocking down podocalyxin by RNA interference resulted in retardation of cell growth and epithelial polarization. Taken together, the data suggest that podocalyxin and NHERF-2 could be part of an early apical polarity scaffolding system based on PDZ-binding and PDZ-containing proteins. info:eu-repo/classification/ddc/570 ddc:570
27	Lysosome biogenesis during osteoclastogenesis Apfeldorfer, Coralie 23 November 2006 (has links) Lysosomes are acidic, hydrolase-rich vesicles capable of degrading most biological macromolecules. During the past several decades, much has been learned about different aspects of lysosome biogenesis. The selective phosphorylation of mannose residues on lysosomal enzymes, in conjunction with specific receptors for the mannose-6-phosphate recognition marker, has been found to be largely responsible for the targeting of newly synthesized lysosomal enzymes to lyzosomes. It is known that lysosomes receive input from both the endocytotic and biosynthetic pathways. Nevertheless the exact molecular mechanisms responsible for sorting of the biosynthetic imput involved in the lysosome biogenesis is still a matter of debate. Because osteoclast precursors do not secrete their lysosomal enzymes and osteoclasts do, the observation of modifications occuring during osteoclastogenesis is a good model to observe mechanisms responsible for lysosomal enzymes traffic. Osteoclasts are bone-degrading cells. To perform this specific task they have to reorganise the sorting of their lysosomal enzymes to be able to target them toward the bone surface in mature cells. Since few years, the differentiation of osteoclasts in vitro did help to study these cells. Osteoclast morphology has been therefore already well studied, and the nature of their specific membrane domains is now established. Sensing the proximity of a bone-like surface the cell reorganises its cytoskeleton, and creates specific membrane domains: an actin-rich ring-like zone (named actin ring) surrounded by highly ruffled membrane (named the ruffled border) where enzymes are secreted, while subsequent bone degradation products are endocytosed. Endocytosed material is then transported through the cell inside transcytotic vesicles and released at the top of the cell in an area named the functional secretory domain. Several molecular machineries are thought to control these different phenomena. The main purpose of this thesis was to identify the major regulators of lysosomal enzymes secretion and therefore to identify the molecular switches responsible for such a membrane traffic re-organisation. info:eu-repo/classification/ddc/570 ddc:570
28	ATP induced intracellular calcium response and purinergic signalling in cultured suburothelial myofibroblasts of the human bladder Cheng, Sheng 11 June 2012 (has links) (PDF) Suburothelial myofibroblasts (sMF) are located underneath the urothelium in close proximity to afferent nerves and show spontaneous calcium activity in vivo and in vitro. They express purinergic receptors and calcium transients can be evoked by ATP. Therefore they are supposed to be involved in afferent signaling of the bladder fullness. Myofibroblast cultures, established from cystectomies, were challenged by exogenous ATP in presence or absence of purinergic antagonist. Fura-2 calcium imaging was used to monitor ATP (10-16 to 10-4 mol/l) induced alterations of calcium activity. Purinergic receptors (P2X1, P2X2, P2X3) were analysed by confocal immunofluorescence. We found spontaneous calcium activity in 55.18% ± 1.65 (mean ± SEM) of the sMF (N=48 experiments). ATP significantly increased calcium activity even at 10-16 mol/l. The calcium transients were partially attenuated by subtype selective antagonist (TNP-ATP, 1μM; A-317491, 1μM), and were mimicked by the P2X1, P2X3 selective agonist α,β-methylene ATP. The expression of purinergic receptor subtypes in sMF was confirmed by immunofluorescence. Our experiments demonstrate for the first time that ATP can modulate spontaneous activity and induce intracellular Ca2+ response in cultured sMF at very low concentrations, most likely involving ionotropic P2X receptors. These findings support the notion that sMF are able to register bladder fullness very sensitively, which predestines them for the modulation of the afferent bladder signaling in normal and pathological conditions. Harnblase Physiologie Dranginkontinenz Myofibroblasten Interstitielle Zellen Zellkultur ATP Calcium Imaging purinerge Rezeptoren purinerge Signalverarbeitung konfokale Laserscanningmikroskopie CLSM spontane Kalziumaktivität urinary bladder physiology urgency myofibroblast interstitial cell cultured cells ATP Calcium Imaging purinergic signalling purinergic receptor immunofluorescence confocal laserscanning microscopy CLSM spontaneous calcium activity ddc:610 Urologische Klinik Urologie ATP Calciumion Zellkultur Biomembran Purinozeptor
29	Einfache Modelle für komplexe Biomembranen / Simple Models For Complex Biomembranes Schultze, Hergen 06 October 2003 (has links) No description available. 530 Physik Mathematics and Computer Science Weiche Materie Komplexes Fluid Biomembran Cluster Entmischung Gittergas Lipid Protein Adsorbat Krümmung Saft Matter Complex Fluid Biomembrane Cluster Demixing Lattice Gas Lipid Protein Adsorbate Curvature 33.25 33.64 RDI 700: Statistische Physik Quantenstatistik
30	ATP induced intracellular calcium response and purinergic signalling in cultured suburothelial myofibroblasts of the human bladder: ATP induced intracellular calcium response and purinergic signalling in cultured suburothelial myofibroblasts of thehuman bladder Cheng, Sheng 22 May 2012 (has links) Suburothelial myofibroblasts (sMF) are located underneath the urothelium in close proximity to afferent nerves and show spontaneous calcium activity in vivo and in vitro. They express purinergic receptors and calcium transients can be evoked by ATP. Therefore they are supposed to be involved in afferent signaling of the bladder fullness. Myofibroblast cultures, established from cystectomies, were challenged by exogenous ATP in presence or absence of purinergic antagonist. Fura-2 calcium imaging was used to monitor ATP (10-16 to 10-4 mol/l) induced alterations of calcium activity. Purinergic receptors (P2X1, P2X2, P2X3) were analysed by confocal immunofluorescence. We found spontaneous calcium activity in 55.18% ± 1.65 (mean ± SEM) of the sMF (N=48 experiments). ATP significantly increased calcium activity even at 10-16 mol/l. The calcium transients were partially attenuated by subtype selective antagonist (TNP-ATP, 1μM; A-317491, 1μM), and were mimicked by the P2X1, P2X3 selective agonist α,β-methylene ATP. The expression of purinergic receptor subtypes in sMF was confirmed by immunofluorescence. Our experiments demonstrate for the first time that ATP can modulate spontaneous activity and induce intracellular Ca2+ response in cultured sMF at very low concentrations, most likely involving ionotropic P2X receptors. These findings support the notion that sMF are able to register bladder fullness very sensitively, which predestines them for the modulation of the afferent bladder signaling in normal and pathological conditions.:1. Introduction............................................................................ 1 1.1. Anatomy and histology of the human urinary bladder..................... 1 1.1.1. Anatomy of the human urinary bladder..................................... 1 1.1.2. Structure of the human urinary bladder wall............................... 2 1.2. Normal bladder function and bladder dysfunction.......................... 3 1.2.1 Normal bladder function......................................................... 3 1.2.2 Sensory aspect.................................................................... 4 1.2.3 Overactivity or hypersensitivity of bladder.................................. 5 1.3 The role of functional cell types and interaction in urinary bladder... 6 1.3.1 The role of urothelium.......................................................... 7 1.3.2Theroleofsuburotheliamyofibroblast...................................... 7 1.3.3Theroleofdetrusorsmoothmusclecells.................................. 9 1.3.4 Possible interactions in urinary bladder cell types........................ 10 1.4 ATP function and Purinergic signalling in bladder........................... 11 1.5 Spontaneous activity of bladder................................................... 13 2. Objective.................................................................................. 15 3. Material and methods............................................................... 16 3.1. Ethics Statement........................................................................ 16 3.2. Cell preparation.......................................................................... 16 3.3. Solutions and chemicals............................................................. 19 3.4. Intracellular calcium measurements............................................. 20 2.4.1. Preparing cells for Calcium Imaging.......................................... 20 2.4.2. Preparing workspace of calcium imaging................................... 20 2.4.3. Calcium imaging recording...................................................... 22 3.5 Data analysis with automated Fluorescence analysis..................... 22 3.6 Confocal Immunofluorescence.................................................... 25 3.7 Statistics................................................................................. 26 4. Results.................................................................................. 27 4.1 Spontaneous calcium activity of sMF........................................... 27 4.2 ATP effects on calcium response in sMF...................................... 27 4.3 Analysis of purinergic receptors involved.................................... 30 3.3.1 Agonist stimulation.............................................................. 30 3.3.2 Signal inhibition by specific antagonists................................... 31 4.4 Confocal immunofluorescence of purinergic receptors.................. 32 5. Discussion............................................................................. 34 5.1 Myofibroblast identification....................................................... 34 5.2 Spontaneous activity in the bladder............................................ 36 5.3 ATP modulated calcium activity in sMF....................................... 37 5.4 purinergic signalling in sMF........................................................ 39 6. Summary................................................................................ 42 7. References.............................................................................. 45 Declaration............................................................................. 50 Acknowledgements................................................................. 51 info:eu-repo/classification/ddc/610 ddc:610

Search results