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Showing 21 to 30 of 30 (0.019 seconds)Spelling suggestions: "subject:"[een] BIOMEMBRANE"" "subject:"[enn] BIOMEMBRANE""
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Polymorphism of Biomembranes at the NanoscaleSatarifard, 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.
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Entwicklung und Evaluation von Konzepten und Formaten zum Wissenstransfer von der Forschung in die Schule und Öffentlichkeit - Am Beispiel des SFB 803 / Development and Evaluation of Concepts and Formats of Knowledge Transfer from Research to Schools and the Public - By Way of CRC 803von Hoff, Elena 12 October 2020 (has links)
No description available.
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Chromatographic Studies of Solute Interactions with Immobilized Red Blood Cells and BiomembranesGottschalk, Ingo January 2002 (has links)
<p>Specific and non-specific interactions of solutes with immobilized biomembranes were studied using chromatographic methods. Liposomes, proteoliposomes and red blood cell (RBC) membrane vesicles were immobilized by a freeze-thawing procedure, whereas whole RBCs were adsorbed in the gel beds using electrostatic interaction, binding to wheat germ agglutinin (WGA) or the streptavidin-biotin interaction. </p><p>Superporous agarose gel with coupled WGA was the most promising matrix for RBC adsorption and allowed frontal chromatographic analyses of the cells for about one week. Dissociation constants for the binding of cytochalasin B and glucose to the glucose transporter GLUT1 were determined under equilibrium conditions. The number of cytochalasin B-binding sites per GLUT1 monomer was calculated and compared to corresponding results measured on free and immobilized membrane vesicles and GLUT1 proteoliposomes. This allowed conclusions about the protein´s binding state <i>in vitro</i> and <i>in vivo</i>. </p><p>Partitioning of drugs into biomembranes was quantified and the system was suggested as a screening method to test for possible intestinal absorption of drug candidates. We also studied how membrane partitioning of drugs is affected by the presence of integral membrane proteins or of charged phospholipids.</p><p>An attempt to combine the theory for specific binding and membrane partitioning of solutes in a single equation is briefly presented. </p>
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Affinity-, Partition- and Permeability Properties of the Human Red Blood Cell Membrane and Biomembrane Models, with Emphasis on the GLUT1 Glucose TransporterLagerquist Hägglund, Christine January 2003 (has links)
<p>The human glucose transporter GLUT1 is abundant in red blood cells, the blood-brain barrier and epithelial cells, where it mediates the transport of the energy metabolite, glucose. In the present work some properties of GLUT1, including affinity binding of both substrates and inhibitors, transport rates as well as permeabilities of aromatic amino acids and drug-membrane interactions were analyzed by chromatographic methods.</p><p>Reconstitution by size-exclusion chromatography on Superdex 75 from a detergent with a low CMC that provides monomeric GLUT1 was examined regarding D-glucose- and CB binding as well as D-glucose transport. Upon steric immobilization in Superdex 200 gel beads, residual detergent could be washed away and dissociation constants in the same range as reported for binding to GLUT1 reconstituted from other detergents were obtained. The transport rate into the GLUT1 proteoliposomes was low, probably due to residual detergent. Binding to GLUT1 at different pH was analyzed and the affinity of glucose and GLUT1 inhibitors was found to decrease with increasing pH (5–8.7). The average number of cytochalasin B-binding sites per GLUT1 monomers was, in most cases, approximately 0.4. GLUT1 may work as a functional monomer, dimer or oligomer. To determine whether GLUT1 was responsible for the transport of the aromatic amino acids tyrosine and tryptophan, uptake values and permeabilities of these amino acids into liposomes and GLUT1 proteoliposomes were compared to the permeabilities of D- and L- glucose in the same systems. Dihydrocytochalasin B was identified to be a new inhibitor of tyrosine and tryptophan transport into red blood cells. Ethanol turned out to inhibit the specific binding between CB and GLUT1 and also to decrease the partitioning of CB and drugs into lipid bilayers. A capacity factor for drug partitioning into membranes that allows comparison between columns with different amount of immobilized lipids was validated, and turned out to be independent of flow rate, amount of lipids and drug concentration in the ranges tested.</p>
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Affinity-, Partition- and Permeability Properties of the Human Red Blood Cell Membrane and Biomembrane Models, with Emphasis on the GLUT1 Glucose TransporterLagerquist Hägglund, Christine January 2003 (has links)
The human glucose transporter GLUT1 is abundant in red blood cells, the blood-brain barrier and epithelial cells, where it mediates the transport of the energy metabolite, glucose. In the present work some properties of GLUT1, including affinity binding of both substrates and inhibitors, transport rates as well as permeabilities of aromatic amino acids and drug-membrane interactions were analyzed by chromatographic methods. Reconstitution by size-exclusion chromatography on Superdex 75 from a detergent with a low CMC that provides monomeric GLUT1 was examined regarding D-glucose- and CB binding as well as D-glucose transport. Upon steric immobilization in Superdex 200 gel beads, residual detergent could be washed away and dissociation constants in the same range as reported for binding to GLUT1 reconstituted from other detergents were obtained. The transport rate into the GLUT1 proteoliposomes was low, probably due to residual detergent. Binding to GLUT1 at different pH was analyzed and the affinity of glucose and GLUT1 inhibitors was found to decrease with increasing pH (5–8.7). The average number of cytochalasin B-binding sites per GLUT1 monomers was, in most cases, approximately 0.4. GLUT1 may work as a functional monomer, dimer or oligomer. To determine whether GLUT1 was responsible for the transport of the aromatic amino acids tyrosine and tryptophan, uptake values and permeabilities of these amino acids into liposomes and GLUT1 proteoliposomes were compared to the permeabilities of D- and L- glucose in the same systems. Dihydrocytochalasin B was identified to be a new inhibitor of tyrosine and tryptophan transport into red blood cells. Ethanol turned out to inhibit the specific binding between CB and GLUT1 and also to decrease the partitioning of CB and drugs into lipid bilayers. A capacity factor for drug partitioning into membranes that allows comparison between columns with different amount of immobilized lipids was validated, and turned out to be independent of flow rate, amount of lipids and drug concentration in the ranges tested.
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Chromatographic Studies of Solute Interactions with Immobilized Red Blood Cells and BiomembranesGottschalk, Ingo January 2002 (has links)
Specific and non-specific interactions of solutes with immobilized biomembranes were studied using chromatographic methods. Liposomes, proteoliposomes and red blood cell (RBC) membrane vesicles were immobilized by a freeze-thawing procedure, whereas whole RBCs were adsorbed in the gel beds using electrostatic interaction, binding to wheat germ agglutinin (WGA) or the streptavidin-biotin interaction. Superporous agarose gel with coupled WGA was the most promising matrix for RBC adsorption and allowed frontal chromatographic analyses of the cells for about one week. Dissociation constants for the binding of cytochalasin B and glucose to the glucose transporter GLUT1 were determined under equilibrium conditions. The number of cytochalasin B-binding sites per GLUT1 monomer was calculated and compared to corresponding results measured on free and immobilized membrane vesicles and GLUT1 proteoliposomes. This allowed conclusions about the protein´s binding state in vitro and in vivo. Partitioning of drugs into biomembranes was quantified and the system was suggested as a screening method to test for possible intestinal absorption of drug candidates. We also studied how membrane partitioning of drugs is affected by the presence of integral membrane proteins or of charged phospholipids. An attempt to combine the theory for specific binding and membrane partitioning of solutes in a single equation is briefly presented.
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Quantitation, Purification and Reconstitution of the Red Blood Cell Glucose Transporter GLUT1Zuo, Shusheng January 2005 (has links)
<p>The human glucose transporter GLUT1 facilitates glucose to be accumulated on the other side of the cell membrane. The functional state of GLUT1 is uncertain due to diversity of the reports. In this thesis, the activity of red blood cell GLUT1 was extensively studied to further characterize this protein.</p><p>The human red blood cell membranes were stripped to become vesicles with low-ionic alkaline solution in the presence or absence of dithioerithritol. The supernatant of partially solubilized membrane vesicles provided approximately 65% of the vesicle proteins. GLUT1 purified from this supernatant showed a little high-affinity cytochalasin B binding activity. On the other hand, the vesicles stripped with dithioerythritol provided mostly monomeric GLUT1 and those without dithioerythritol provided monomeric and oligomeric GLUT1. MALDI-ToF-MS detected variant GLUT1 fragments between the two preparations. Residual endogenous phospholipids per GLUT1 also showed difference. However, the equilibrium exchange of glucose was retained for both GLUT1 preparations. Cytochalasin B-binding activity of GLUT1 in streptoavidin-biotin-immobilized red blood cells showed that both dissociation constant and binding sites per GLUT1 fell between those of wheat germ lectin-immobilized red blood cells with or without polylysine coating, which indicated the switching of two cytochalasin B-binding states of GLUT1. It is concluded that GLUT1 in red blood cells contains approximately two equal portions, monomeric with high-affinity cytochalasin B-binding activity and oligomeric without high-affinity cytochalasin B-binding activity. In the partial solubilization of the membrane vesicles, GLUT1 which does not have high-affinity cytochalasin B-binding activity is pooled. This might provide a resolution to select oligomerically and functionally different GLUT1 for crystallization.</p><p>In addition a modified micro-Bradford assay with CaPE precipitation was developed to achieve a routine quantitation method for membrane proteins and the effects of cholesterol and PEG(5000)-DSPE on reconstituted GLUT1 were preliminarily determined.</p>
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Quantitation, Purification and Reconstitution of the Red Blood Cell Glucose Transporter GLUT1Zuo, Shusheng January 2005 (has links)
The human glucose transporter GLUT1 facilitates glucose to be accumulated on the other side of the cell membrane. The functional state of GLUT1 is uncertain due to diversity of the reports. In this thesis, the activity of red blood cell GLUT1 was extensively studied to further characterize this protein. The human red blood cell membranes were stripped to become vesicles with low-ionic alkaline solution in the presence or absence of dithioerithritol. The supernatant of partially solubilized membrane vesicles provided approximately 65% of the vesicle proteins. GLUT1 purified from this supernatant showed a little high-affinity cytochalasin B binding activity. On the other hand, the vesicles stripped with dithioerythritol provided mostly monomeric GLUT1 and those without dithioerythritol provided monomeric and oligomeric GLUT1. MALDI-ToF-MS detected variant GLUT1 fragments between the two preparations. Residual endogenous phospholipids per GLUT1 also showed difference. However, the equilibrium exchange of glucose was retained for both GLUT1 preparations. Cytochalasin B-binding activity of GLUT1 in streptoavidin-biotin-immobilized red blood cells showed that both dissociation constant and binding sites per GLUT1 fell between those of wheat germ lectin-immobilized red blood cells with or without polylysine coating, which indicated the switching of two cytochalasin B-binding states of GLUT1. It is concluded that GLUT1 in red blood cells contains approximately two equal portions, monomeric with high-affinity cytochalasin B-binding activity and oligomeric without high-affinity cytochalasin B-binding activity. In the partial solubilization of the membrane vesicles, GLUT1 which does not have high-affinity cytochalasin B-binding activity is pooled. This might provide a resolution to select oligomerically and functionally different GLUT1 for crystallization. In addition a modified micro-Bradford assay with CaPE precipitation was developed to achieve a routine quantitation method for membrane proteins and the effects of cholesterol and PEG(5000)-DSPE on reconstituted GLUT1 were preliminarily determined.
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Einfache Modelle für komplexe Biomembranen / Simple Models For Complex BiomembranesSchultze, Hergen 06 October 2003 (has links)
No description available.
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Probing cellular mechano-sensitivity using biomembrane-mimicking cell substrates of adjustable stiffnessLin, Yu-Hung 12 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / It is increasingly recognized that mechanical properties of substrates play a pivotal role in the regulation of cellular fate and function. However, the underlying mechanisms of cellular mechanosensing still remain a topic of open debate. Traditionally, advancements in this field have been made using polymeric substrates of adjustable stiffness with immobilized linkers. While such substrates are well suited to examine cell adhesion and migration in an extracellular matrix environment, they are limited in their ability to replicate the rich dynamics found at cell-cell interfaces. To address this challenge, we recently introduced a linker-functionalized polymer-tethered multi-bilayer stack, in which substrate stiffness can be altered by the degree of bilayer stacking, thus allowing the analysis of cellular mechanosensitivity. Here, we apply this novel biomembrane-mimicking cell substrate design to explore the mechanosensitivity of C2C12 myoblasts in the presence of cell-cell-mimicking N-cadherin linkers. Experiments are presented, which demonstrate a relationship between the degree of bilayer stacking and mechanoresponse of plated cells, such as morphology, cytoskeletal organization, cellular traction forces, and migration speed. Furthermore, we illustrate the dynamic assembly of bilayer-bound N-cadherin linkers underneath cellular adherens junctions. In addition, properties of individual and clustered N-cadherins are examined in the polymer-tethered bilayer system in the absence of plated cells.
Alternatively, substrate stiffness can be adjusted by the concentration of lipopolymers in a single polymer-tethered lipid bilayer. On the basis of this alternative cell substrate concept, we also discuss recent results on a linker-functionalized single polymer-tethered bilayer substrate with a lateral gradient in lipopolymer concentration (substrate viscoelasticity). Specifically, we show that the lipopolymer gradient has a notable impact on spreading, cytoskeletal organization, and motility of 3T3 fibroblasts. Two cases are discussed: 1. polymer-tethered bilayers with a sharp boundary between low and high lipopolymer concentration regions and 2. polymer-tethered bilayers with a gradual gradient in lipopolymer concentration.
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