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Characterization of Membrane Permeability and Polymer-Stabilized Model MembranesMa, Yaning January 2007 (has links)
The permeability of lipid bilayer membranes to glucose and carboxyfluorescein has been studied in model membranes. Using an enzyme assay, the permeability of glucose was monitored spectrometrically with both large and giant unilamellar vesicles (LUVs and GUVs). The permeability of carboxyfluorescein was studied by entrapping the dye and monitoring its leakage over time from a single GUV. Permeability study using GUVs may provide new information that cannot be obtained from LUVs.The stability of lipid membranes was enhanced by incorporating polymer scaffold. LUVs were prepared with hydrophobic monomers partitioned and then polymerized inside the hydrophobic interior of the lipid bilayers. The sizes of the formed polymers were characterized using gel permeation chromatography and mass spectrometry. This study suggests that large molecular weight polymers were formed inside the lipid bilayers and that the stability of the membranes is related to the size of the polymers.
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Inquiry of Lipid Membranes Interacting with Functional Peptides and Polyphenol Drug MoleculesHo, Chian Sing 24 June 2016 (has links)
Cellular membranes are important targets for many membrane-active peptides and drug compounds. Here we are interested in deciphering how lipid membranes are perturbed by several membrane-active molecules, including the transmembrane domain of the influenza M2 protein (M2TM), aggregates formed by a synthetic polyglutamine peptide, and three polyphenol compounds (i.e., tamoxifen, genistein, and verapamil). We employ phase-separated ternary lipid model membranes in the form of giant unilamellar vesicles (GUVs) to simulate raft-like structures that have been proposed to govern many important processes in plasma membranes (e.g., intracellular singling and trafficking). Specifically, we use fluorescent microscopy to interrogate how those membrane additives modulate the phase behavior of free-standing GUVs, as well as the miscibility transition temperature (Tm). We find that M2TM increases Tm and causes vesicle budding; polyglutamine aggregates disrupt lipid membranes; and the three polyphenol compounds exert disparate effects on GUV Tm.
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Hemifusion and lateral lipid domain partition in lipid membranes of different complexityNikolaus, Jörg 14 December 2011 (has links)
Die Fusion von Membranen erfordert die Verschmelzung von zwei Phospholipiddoppel-schichten, wobei dies über dieselben Zwischenschritte abzulaufen scheint. Eine lokale Störung (‚Stalk’) stellt eine erste Verbindung der äußeren Membranhälften dar, die anschließend lateral expandiert und ein Hemifusionsdiaphragma (HD) bildet. Das Öffnen einer Fusionspore im HD führt zur vollständigen Fusion. Mittels konfokaler Mikroskopie wurde die Fusion von Giant unilamellar vesicles (GUVs) mit negativ geladenen Lipiden und transmembranen (TM) Peptiden in Anwesenheit von zweiwertigen Kationen beobachtet, wobei die Peptide bei der HD Entstehung völlig verdrängt wurden. Eine detaillierte Analyse zeigte, dass es sich bei diesem Mikrometer-großen Bereich um ein HD handelt, dessen Größe von der Lipidzusammensetzung und Peptidkonzentration in den GUVs abhängt. Laterale Lipiddomänen gelten als entscheidend für Signal- und Sortierungsprozesse in der Zelle. Liquid ordered (Lo) Domänen in Modellsystemen wie GUVs ähneln den mit Sphingo-lipiden und Cholesterol angereicherten biologischen Raft-Domänen, allerdings scheinen Membraneigenschaften wie die Lipidpackung sich von biologischen Membranen zu unterscheiden. In diesem Zusammenhang wird die Sortierung des TM-verankerten Hemag-glutinin (HA) des Influenzavirus und von lipidverankerten Ras-Proteinen in GUVs wie auch in abgelösten Plasmamembran-Ausstülpungen (GPMVs) untersucht. HA Protein und TM-Pepitde von HA wurden ausschließlich (GUVs) bzw. vorwiegend (GPMVs) in der liquid disordered (Ld) Domäne gefunden. K-Ras wurde inmitten der Ld detektiert, während N-Ras zur Lo/Ld Grenzlinie diffundierte. Diese Ergebnisse werden im Zusammenhang mit den Unterschieden der Lipidpackung innerhalb der verschiedenen membranverankerten Systeme diskutiert. Es ist wahrscheinlich, dass die Bildung, Größe und Stabilität sowie die physikalischen Eigenschaften der Lipiddomänen in biologischen Membranen stark von Protein-Lipid-Wechsel-wirkungen beeinflusst werden. / Membrane fusion is ubiquitous in life and requires remodelling of two phospholipid bilayers. Fusion likely proceeds through similar sequential intermediates. A stalk between the contacting leaflets forms and radially expands into a hemifusion diaphragm (HD) wherein finally a fusion pore opens up. Direct experimental verification of this key structure is difficult due to its transient nature. Confocal microscopy was used to visualize the fusion of giant unilamellar vesicles (GUVs) comprising negatively charged phosphatidylserine and fluorescent transmembrane (TM) entities in the presence of divalent cations. A complete displacement of TM peptides preceded full fusion. This is consistent with HD formation. Detailed analysis provided proof that the micrometer sized structures are in fact HDs. HD size is dependent on lipid composition and peptide concentration. Lateral lipid domain formation is believed to be essential for sorting and signalling processes in the cell. Liquid ordered (Lo) domains in model systems like GUVs resemble biological rafts enriched in sphingolipids and cholesterol, but their physical properties seem distinct from biological membranes as judged by e.g. lipid order and packing. In this context the sorting of TM anchored influenza virus hemagglutinin (HA) and different lipid anchored Ras proteins is studied in GUVs and giant plasma membrane derived vesicles (GPMVs). Authentic HA or the TM domain peptides were sorted exclusively (GUVs) or predominantly (GPMVs) to the liquid disordered (Ld) domains. Whereas K-Ras was found in the bulk Ld domains, N-Ras diffuses to the Lo/Ld interface. These results are discussed with respect to differences in lipid packing in the different membrane systems and regarding the membrane anchors and their hydrophobic matching. The results suggest that the formation, size and stability as well as the physical properties of lipid domains in biological membranes are tightly regulated by protein-lipid interactions.
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