Properties of model biological membranes

Dewolf, Christine Elizabeth

January 1996

No description available.

571.4

Zur Bedeutung von Zytoskelett-Membran-Verbindungen für die gerichtete HCI-Sekretion von Parietalzellen

Jöns, Thomas

16 May 2001

Die in der vorliegenden Habilitationsschrift zusammengefaßten Publikationen stellen Untersuchungen zu zwei Themenschwerpunkten dar: 1. Verankerungsmechanismen von Membranproteinen der basolateralen und der apikalen Plasmamembrandomäne der Parietalzellen mit dem Membranzytoskelett und 2. die regulierte Fusion von zytoplasmatischen Vesikeln mit der apikalen Plasmamembran dieser Zellen. Die strukturell und molekular sehr unterschiedlich gestaltete apikale und basolaterale Membrandomäne der Parietalzellen sollte funktionell charakterisiert und die Mechanismen der Membranumbauvorgänge aufgeklärt werden, die nach Aktivierung der Zellen im apikalen Membrankompartiment ablaufen. Für die strukturelle Stabilität der basolateralen Domäne spielt wahrscheinlich die Verankerung von AE2 über das Verknüpfungsprotein Ankyrin mit dem Membranzytoskelett eine wichtige Rolle. Die apikale Membrandomäne der Parietalzellen kann in drei Kompartimente unterteilt werden. Die freie apikale Membran, die canalikuläre Membran und die Membranen der tubulären Vesikel. Entlang der freien apikalen und der canaliculären Plasmamembran kommen wie auf der basolateralen Seite die Zytoskelett-Proteine Actin und Spectrin vor. Nach unseren Untersuchungen könnte es während der Sekretionsphase zu einer temporären Verbindung von H+,K+-ATPase Molekülen mit dem Membranzytoskelett kommen. Diese Verbindung wird wahrscheinlich durch das Verknüpfungsprotein Ezrin vermittelt. Der Mechanismus des Fusionsvorgangs der tubulären Vesikel mit der canaliculären Membran war bisher nicht bekannt. In Parietalzellen konnten die neuronalen SNARE-Proteine Synaptobrevin 2, Syntaxin 1 und SNAP25 sowie das zur Familie der kleinen G-Proteine gehörende Protein Rab3A und die Regulatorproteine NSF und alpha/beta SNAP nachgewiesen werden. Das in Parietalzellen gefundene Verteilungsmuster der SNARE-Proteine entspricht nicht der klassischen Vorstellung einer heterotypischen Membranfusion, vielmehr entspricht diese Verteilung einer homotypischen Fusion, wie sie für Vakuolen in Hefezellen beschrieben wurde. Die Bedeutung der SNARE-Proteine für die Fusion der tubulären Vesikel mit der canaliculären Membran und damit für die Steigerung der HCl-Sekretion konnte durch Inkubation der Zellen mit Tetanus Neurotoxin (TeNt) gezeigt werden. Die Behandlung der Parietalzellen mit TeNt führte zum vollständigen Ausbleiben der, nach Stimulation mit cAMP bei Kontrollzellen beobachteten Erhöhung, der Säuresekretion / The publications summarized here cover two topics: 1. the anchorage mechanism of membrane proteins of the basolateral and the apical plasma membrane with the membrane cytoskeleton of parietal cells and 2. the regulated fusion of cytoplasmic vesicles with the apical plasma membrane of these cells. It was the aim of these studies to characterize the structural and molecular differences between the apical and basolateral membrane domains in parietal cells. Moreover the mechanisms involved in membrane traffic within the apical membrane compartment following stimulation were investigated. We found that anchorage of AE2 with the membrane cytoskeleton through the linkage protein ankyrin seems to be important for the stability of the basolateral membrane. The apical membrane domain of parietal cells can be subdivided into three compartments. The free apical membrane, the canalicular membrane and the tubulovesicular membrane. The cytoskeletal proteins spectrin and actin can be found at the basolateral, the free apical and the canalicular membrane. We have shown that the H+K+-ATPase molecules appear to be temporary linked to the membrane cytoskeleton during acid-secretion. This contact is most likely mediated by the linker-protein ezrin. Until now the mechanism of fusion of the tubulovesicles with the canalicular membrane was unknown. In parietal cells the neuronal SNARE-proteins synaptobrevin 2, Syntaxin 1, SNAP25, the small G-protein rab3A, and the regulatory proteins NSF and alpha/beta-SNAP were detected. The subcellular distribution of these proteins does not support the notion of a neuron-like heterotypic fusion. Instead it shows similarity with the homotypic fusion process of vacuoles in yeast. The importance of SNARE-proteins for the fusion of tubulovesicles with the canalicular membrane and, by consequence also for the increase of acid-secretion was shown by incubation of the cells with tetanus neurotoxin (TeNt). The measurable increase of acid secretion by parietal cells after stimulation with c-AMP was inhibited completely through an incubation with TeNt.

Parietalzellen

Polarität

Membranzytoskelett

SNARE-Proteine

AE2

Ankyrin

Ezrin

Parietal cells

polarity

membrane cytoskeleton

SNARE-proteins

AE2

ankyrin

ezrin

610 Medizin

33 Medizin

WE 2600

ddc:610

Critical fluctuations and anomalous diffusion in two-component lipid membranes: Monte Carlo simulations on experimentally relevant scales

Ehrig, Jens

18 February 2013

This work addresses properties of two-component lipid membranes on the experimentally relevant spatial scales of order of a micrometer and time intervals of order of a second by means of lattice-based Monte Carlo (MC) simulations. To be able to do that with reasonable computational efforts the lipid membrane is modeled as a square lattice of lipid molecules with next-neighbor interaction. This allows for efficient computation and thus provides a large-scale simulation with which it was possible to obtain important results previously not reported in simulation studies of lipid membranes. After properly tuning the next-neighbor interaction energies the simulation reproduces the experimental phase diagram of the DMPC/DSPC lipid system which is used as a model system in this work. Beyond that, the MC simulation provides a more detailed description of the phase behavior of the lipid mixture than the experimental data. It is found that, within a certain range of lipid compositions, the phase transition from the fluid phase to the fluid–gel phase coexistence proceeds via near-critical fluctuations, while for other lipid compositions this phase transition has a quasi-abrupt character. The complete combined state and component phase diagram is constructed by structure function analysis which confirms the existence of a critical point in the system. The dynamics of membrane coarsening after an abrupt temperature quench to the fluid–gel coexistence region of the phase diagram are studied. In this context, it is found that lateral diffusion of lipids plays an important role in the fluid–gel phase separation process. Dynamic scaling is observed only if the ratio of gel and fluid phase in the membrane stays constant in time. The line tension characterizing lipid domains in the fluid–gel coexistence region is found to be in the pN range thus matching values both predicted theoretically and measured experimentally. When approaching the critical point, the line tension, the inverse correlation length of fluid–gel spatial fluctuations, and the corresponding inverse order parameter susceptibility of the membrane vanish in agreement with recent experimental findings for model lipid membranes. By simulating single particle tracking and fluorescence correlation spectroscopy experiments it is found that in the presence of near-critical fluctuations lipid molecules show transient subdiffusive behavior, which is a new result important for understanding the origins of subdiffusion in cell membranes which are believed to be close to a critical point. The membrane–cytoskeleton interaction strongly affects phase separation, enhances subdiffusion, and eventually leads to hop diffusion of lipids. Thus, a minimum realistic model for membrane rafts showing the features of both microscopic phase separation and subdiffusion is established.

Monte Carlo Simulation

Lipidmembran

anomale Diffusion

kritische Fluktuationen

Membran--Zytoskelett-Interaktion

Monte Carlos simulations

lipid membrane

anomalous diffusion

critical fluctuations

membrane--cytoskeleton interactions

ddc:570

rvk:WE 5000

rvk:SK 820

Critical fluctuations and anomalous diffusion in two-component lipid membranes: Monte Carlo simulations on experimentally relevant scales

Ehrig, Jens

23 November 2012

This work addresses properties of two-component lipid membranes on the experimentally relevant spatial scales of order of a micrometer and time intervals of order of a second by means of lattice-based Monte Carlo (MC) simulations. To be able to do that with reasonable computational efforts the lipid membrane is modeled as a square lattice of lipid molecules with next-neighbor interaction. This allows for efficient computation and thus provides a large-scale simulation with which it was possible to obtain important results previously not reported in simulation studies of lipid membranes. After properly tuning the next-neighbor interaction energies the simulation reproduces the experimental phase diagram of the DMPC/DSPC lipid system which is used as a model system in this work. Beyond that, the MC simulation provides a more detailed description of the phase behavior of the lipid mixture than the experimental data. It is found that, within a certain range of lipid compositions, the phase transition from the fluid phase to the fluid–gel phase coexistence proceeds via near-critical fluctuations, while for other lipid compositions this phase transition has a quasi-abrupt character. The complete combined state and component phase diagram is constructed by structure function analysis which confirms the existence of a critical point in the system. The dynamics of membrane coarsening after an abrupt temperature quench to the fluid–gel coexistence region of the phase diagram are studied. In this context, it is found that lateral diffusion of lipids plays an important role in the fluid–gel phase separation process. Dynamic scaling is observed only if the ratio of gel and fluid phase in the membrane stays constant in time. The line tension characterizing lipid domains in the fluid–gel coexistence region is found to be in the pN range thus matching values both predicted theoretically and measured experimentally. When approaching the critical point, the line tension, the inverse correlation length of fluid–gel spatial fluctuations, and the corresponding inverse order parameter susceptibility of the membrane vanish in agreement with recent experimental findings for model lipid membranes. By simulating single particle tracking and fluorescence correlation spectroscopy experiments it is found that in the presence of near-critical fluctuations lipid molecules show transient subdiffusive behavior, which is a new result important for understanding the origins of subdiffusion in cell membranes which are believed to be close to a critical point. The membrane–cytoskeleton interaction strongly affects phase separation, enhances subdiffusion, and eventually leads to hop diffusion of lipids. Thus, a minimum realistic model for membrane rafts showing the features of both microscopic phase separation and subdiffusion is established.

info:eu-repo/classification/ddc/570

ddc:570

Jaderný myosin 1 a jeho role v regulaci tenze cytoplazmatické membrány / Nuclear myosin 1 and its role in the regulation of plasma membrane tension

Petr, Martin

January 2014

Myosin 1c (Myo1c) is a molecular motor involved in regulation of tension-gated ion channels, exocytosis, endocytosis, motility and other membrane-related events. Moreover, it acts as a dynamic linker between the cell membrane and cortical actin network, contributing to the maintenance of plasma membrane tension. In contrast, nuclear myosin 1 (NM1), an isoform of Myo1c, has been described only in the nucleus where it participates in various nuclear processes, including transcription or chromatin remodeling. However, although traditionally regarded as exclusively cytoplasmic or nuclear, all myosin 1c isoforms participate in nuclear functions and they are present in the cytoplasm as well. The main focus of this study was to characterize the functional significance of NM1 in the cytoplasm. We have found that NM1 localizes to plasma membrane and shows a uniform punctuated distribution with a high concentration at the cell periphery. Moreover, atomic force microscopy measurements of mouse NM1 KO fibroblasts revealed a significant increase in an overall plasma membrane elasticity in comparison to WT cells, indicating a disruption in the regulation of plasma membrane tension caused by the loss of NM1. Since a higher membrane elasticity and deformability is a characteristic marker of cancer cells,...