Structure and function of neuronal GPI domains

Smith, Karen Louise

January 1999

No description available.

572

Lipid domains; Surface membranes; Plasma

Sondes moléculaires multifonctionnelles pour l'imagerie de fluorecence de membranes cellulaires / Multifonctional molecular probes for fluorescence imaging of cell membranes

Kreder, Rémy

06 March 2015

Conçues à partir d’une approche rationnelle, nous avons créé de nouvelles sondes membranaires permettant l’imagerie de l’organisation de la membrane plasmique cellulaire. Dans ce travail, nous avons d’abord développé un groupe d’outils, à partir du fluorophore solvatochrome Nile Red et de Black Hole Quencher-2, capable de marquer spécifiquement les domaines ordonnés et désordonnés (radeaux) en les identifiant par leur couleur d’émission. Les études cellulaires, à l’aide de ces sondes, suggèrent que la membrane plasmique est composée de deux phases distinctes. Puis dans le but de créer de nouvelles sondes basées sur Nile Red compatibles avec le sérum et fixables par formaldéhyde/glutaraldéhyde, nous avons modifié la sonde, préalablement développée, NR12S avec un groupement PEG ou amino, respectivement. Etonnamment, la sonde PEGylée est rapidement internalisée dans la cellule et le dérivé animo agrège avec l’agent fixant. D’un autre côté,basée sur Nile Red, nous avons conçu une sonde capable de détecter un récepteur donné et de visualiser son environnement lipidique. Initialement, nous avons obtenu des sondes capables d’allumer leur fluorescence en se liant sur le RCPG à l’ocytocine. Puis, nous avons conjugué NR12Spar l’intermédiaire d’un espaceur PEG(12) au ligand de l’intégrine, RGD. Les résultats préliminaires montrent que la molécule peut se lier à la membrane et détecter l’ordre lipidique, cependant les études cellulaires nécessitent un achèvement. Nous avons aussi travaillé sur des sondes membranaires fluorogéniques (turn-on) pour de l’imagerie multi-couleurs. Basées sur le fluorophore3-méthoxychromone, nous avons obtenu des sondes plus brillantes et plus photostables que la sonde développée originellement à partir de 3-hydroxychromone (F2N12S). Grâce à l’important déplacement de Stokes, elles permettent une imagerie de la membrane cellulaire avec une autofluorescence minimale dans la région spectrale bleue, compatible avec les marqueurs communs verts et rouges. Pour finir, basées sur le fluorophore squaraine, nous avons développé trois nouvelles sondes opérant dans la région rouge lointain, qui est particulièrement intéressante pour l’imagerie in vitro et in vivo. Ces sondes montrent une orientation parallèle avec la membrane lipidique, alors que les expériences cellulaires indiquent que seule la sonde avec deux ancres lipidiques est capable de marquer de façon stable la membrane plasmique. Ces sondes développées ici sont prévues pour être utilisées dans la recherche des radeaux lipidiques aussi bien que pour l’imagerie super-résolution et multi-couleurs de cellules vivantes. / Based on rational molecular design, we design new membrane probes that enable fluorescence imaging of cell plasma membrane organization. In this work, we first synthesized a toolkit, based on solvatochromic Nile Red dye and Black Hole Quencher-2, that can stain specifically ordered and disordered lipid domains (rafts) and identify them by the emission color. Cellular studies with these probes suggested that the plasma membrane is composed of two distinct phases. Then,with the idea to make Nile Red-based probes compatible with serum medium and fixable by formaldehyde/glutaraldehyde, we modified previously developed probe NR12S with PEG and aminogroups, respectively. Surprisingly, the PEGylated probe is quickly internalized inside the cell and the amino-derivative aggregates with the fixing agent. On the other hand, based on Nile Red we designed probes capable to detect a given receptor and visualize its lipid environment. Initially, we obtained probes that can turn-on fluorescence on binding to the oxytocin GPCR receptor. Then, we conjugated NR12S through a PEG(12) spacer to the ligand of intergrin, RGD. The first data show that the molecule can bind to the membrane and detect the lipid order, though cellular studies have to be completed. We also worked on fluorogenic (turn-on) membrane probes for multi-color imaging. Based on blue 3-methoxychromone dyes, we obtained probes that are brighter and more photostable than the originally developed probe based on 3-hydroxychromone (F2N12S). Due to large Stocks shift, they enabled cell membrane imaging with minimal auto-fluorescence in the blue spectral region, compatible with common green and red probes. At the end, based on squaraine fluorophore, we developed three new probes operating in the far red region, which is also very interesting for in vitro and in vivo imaging. These dyes show a parallel orientation with the lipid membrane, while the cellular experiments point out that only the probe with two anchor groups is able to stain stably the plasma membrane. The probes developed here are expected to be used for lipid rafts research as well as for super-resolution and multi-color imaging of living cells.

Sondes moléculaires

Radeaux lipidiques

Membrane plasmique

Fluorescence

Membrane probes

Lipid domains

Plasma membrane

Fluorescence

541.3

571.6

Diffusion and Domains: Membrane Structure and Dynamics Studied by Neutron Scattering

Armstrong, Clare L.

January 2013

<p>Biological membranes play host to a number of processes essential for cellular function and are the most important biological interface. The structurally complex and highly dynamic nature of the membrane poses significant measurement challenges, requiring an experimental technique capable of accessing very short, nanometer length scales, and fast, micro-pico second time scales.</p> <p>The experimental work presented in this thesis uses a variety of neutron scattering techniques to study the structure and dynamics of biologically relevant model membrane systems. The main body of this work can be sub-divided into two distinct topics: (1) lateral diffusion of lipid molecules in a bilayer; and (2) the measurement of domains in the membrane.</p> <p>Diffusion is the fundamental mechanism for lipids and proteins to move throughout the lipid matrix of a biological membrane. Despite a strong effort to model lipid diffusion, there is still no coherent model which describes the motion of lipid molecules from less than a lipid-lipid distance to macroscopic length scales. The experiments presented on this topic attempt to extend the range over which diffusion is typically measured by neutron scattering, to initiate the development of a more complete lipid diffusion model.</p> <p>Lipid domains and rafts are thought be platforms for many cellular functions; however, their small size and transient nature makes them notoriously difficult to observe. The penultimate chapter of this thesis provides evidence supporting the existence of domains in a model lipid/cholesterol system by probing of the dynamics of the system. The challenge of observing these structures directly was addressed by modifying the traditional neutron triple-axis spectrometry setup to increase its sensitivity to systems with short-range order. This technique was employed to examine the coexistence of fluid and gel domains in a single-component lipid bilayer system, as well as the presence of highly ordered lipid domains in a model membrane containing cholesterol.</p> / Doctor of Philosophy (PhD)

membrane

lipid diffusion

lipid domains

neutron scattering

lipid bilayer

cholesterol

Biological and Chemical Physics

Biological and Chemical Physics

Structure and dynamics of artificial lipid membranes containing the glycosphingolipid Gb3

Schütte, Ole Mathis

16 July 2015

No description available.

540

lipid domains

fluorescence microscopy

scanning probe microscopy

pore-spanning lipid bilayers

diffusion

glycolipids

Shiga toxin

Chemie  (PPN62138352X)

Formation des sites d'exocytose dans les cellules chromaffines : importance fonctionnelle, régulation et externalisation de l'Annexine A2 / Formation of exocytotic sites in chromaffin cells : functional importance, regulation and externalization of Annexin A2

Gabel, Marion

09 September 2016

L’exocytose est un mécanisme biologique fondamental qui permet la libération du contenu des granules de sécrétion dans le milieu extracellulaire. C’est un processus finement régulé par le calcium qui nécessite entre autre, la réorganisation de la membrane plasmique et la formation de domaines lipidiques. Dans les cellules chromaffines, l’annexine A2, protéine capable de lier les phospholipides et l’actine de manière calcium-dépendante, est responsable de la formation et de la stabilisation de ces plateformes lipidiques. Le résultat majeur de ma thèse concerne l’organisation tridimensionnelle et le rôle de l’actine au niveau des sites d’exocytose. Sachant que la phosphorylation de la tyrosine 23 de l’annexine A2 affecte sa liaison à l’actine et aux membranes, deux acteurs majeurs de l’exocytose, j’ai mis en évidence l’importance fonctionnelle de cette phosphorylation. Une autre conséquence de cette phosphorylation est le passage de l’annexine A2 de la face interne à la face externe de la membrane plasmique. Le mécanisme de sortie et le rôle de l’annexine A2 extracellulaire dans les cellules chromaffines ont également été étudiés. / Exocytosis is a fundamental biological mechanism which allows liberation of the contents of secretory granules into the extracellular medium. This calcium-regulated process requires the formation of lipid domains for the structural and spatial organisation of exocytotic sites. In the chromaffin cell, annexine A2, a calcium-, actin- and lipid-binding protein participates in the formation and stabilization of lipid microdomains. The major advance resulting from my thesis is the elucidation of the three-dimensional organization and the role of actin at the exocytotic site. Phosphorylation of the tyrosine 23 is known to affect the binding of annexin A2 to actin filaments and plasma membrane, two major actors of the exocytotic process and my results highlight the functional importance of this phosphorylation on exocytosis. Furthermore, tyrosine 23 phosphorylation also triggers a translocation of annexin A2 to the external face of the plasma membrane. The role and functional signification of this externalization was also examined.

Annexine A2

Exocytose

Microdomaines lipidiques

Actine

Phosphorylation

Externalisation

Annexin A2

Exocytosis

Lipid domains

Actin

Phosphorylation

Externalization

571.6

572.4

The Role of Lipid Domains and Sterol Chemistry in Nanoparticle-Cell Membrane Interactions

Fuhrer, Andrew B.

January 2020

No description available.

Biomedical Engineering

Biophysics

Engineering

Nanoscience

Lipid Rafts

Lipid Domains

Nanoparticle-Cell Membrane Interactions

Sterol Chemistry

Nanoparticles

Lipids

Membrane Models

Cell Membrane

Hemifusion and lateral lipid domain partition in lipid membranes of different complexity

Nikolaus, Jörg

14 December 2011

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.

Lipiddomänen

Hemifusionsintermediat

Transmembrane Domäne

GUV

Influenza Hemagglutinin

Ras Proteine

hemifusion intermediate

transmembrane domain

giant unilamellar vesicle

lipid domains

Influenza hemagglutinin

Ras proteins

570 Biowissenschaften, Biologie

32 Biologie

WE 5300

ddc:570

Einfluss des Zellkortex auf die Plasmamembran: Modulation von Mikrodomänen in Modellmembranen / Influence of the Cell Cortex on the Plasma Membrane: Modulation of Microdomains in Model Membranes

Orth, Alexander

10 April 2012

Die Struktur der Plasmamembran ist von deren Lipid- und Proteinzusammensetzung abhängig und wird durch die Anbindung an das unterliegende Zytoskelett beeinflusst. Das Ziel der vorliegenden Arbeit war die Untersuchung eines neuen Modellsystems basierend auf po­ren­über­span­nen­den Membranen, welches sowohl die heterogene Lipidzusammensetzung als auch den Einfluss eines unterliegenden Netzwerks berücksichtigt. Lipidmembranen, zusammengesetzt aus der „raft“-ähnlichen Lipidmischung DOPC/Sphingo­myelin/Cho­les­terin (40:40:20), wurden auf porösen, hochgeordneten Siliziumsubstraten mit Po­ren­durch­messern von 0.8, 1.2 und 2.0 µm durch Spreiten und Fusion von Riesenvesikeln (giant unilamellar vesicles, GUVs) präpariert. Die mikroskopische Phasenseparation in koexistierenden flüssig-geordneten (liquid ordered, lo) und flüssig-ungeordneten (liquid disordered, ld) Domänen wurde stark durch das unterliegende poröse Substrat beeinflusst. Die Größe der lo-Domänen konnte durch die Porengröße des Siliziumsubstrats, die Temperatur und den Cholesteringehalt der Membran, welcher durch Zugabe von Methyl-β-Cyclodextrin moduliert wurde, kontrolliert werden. Die Bindung der Shiga Toxin B-Untereinheit (STxB) an po­ren­überspannende Membranen, dotiert mit 5 mol% des Rezeptorlipids Gb3, führte zu einem Anstieg des Anteils der lo-Phase. Außerdem wurde die Bildung von lo-Domänen in nicht-phasenseparierten Membranen, zusammengesetzt aus DOPC/Sphingomyelin/Cholesterin/Gb3 (65:10:20:5), durch die Shiga Toxin-Bindung induziert. Ein Anstieg des Anteils der lo-Phase konnte ebenfalls bei der Bindung der pentameren Cholera Toxin B-Untereinheit (CTxB) an po­ren­überspannende Membranen, dotiert mit 1 mol% des Rezeptorlipids GM1, beobachtet werden. Des Weiteren wurde der Einfluss der chemischen Struktur des Gb3-Moleküls auf die Shiga Toxin-Bindung und die Reorganisation von festkörperunterstützten Membranen (solid supported membranes, SSMs) untersucht. Die STxB-Bindung an α-hydroxyliertes Gb3 erhöhte signifikant den Anteil der lo-Phase, während eine cis-Doppelbindung zur Bildung einer weiteren lo-Phase führte, die vermutlich ungesättigte (Glyko-)Sphingolipide und Cholesterin enthält. Im Falles des ungesättigten Gb3 konnte außerdem eine Kondensation zu größeren Domänen nach der STxB-Bindung beobachtet werden. Die genaue Phasenzuordnung der eingesetzten Glykospingolipide vor der Proteinbindung ist bisher unbekannt. Daher wurde das Phasenverhalten eines fluoreszierenden Polyen-Ga­lac­to­ce­re­bro­sids untersucht, welches bevorzugt in der lo-Phase von GUVs angereichert war. Dieser neue, intrinsische Fluorophor vermag als Grundlage für weitere Studien zum Phasenverhalten von Glykosphingolipiden dienen.

540

Porenüberspannende Membranen

Lipiddomänen

Phasenseparation

Glykolipide

Shiga Toxin

STxB

Cholera Toxin

CTxB

Fluoreszenzmikroskopie

Rasterkraftmikroskopie

AFM

pore-spanning membranes

lipid domains

phase separation

glycolipids

Shiga Toxin

STxB

Cholera Toxin

CTxB

fluorescence microscopy

atomic force microscopy

AFM

Chemie  (PPN62138352X)

On Phase Behaviours in Lipid/Polymer/Solvent/Water Systems and their Application for Formation of Lipid/Polymer Composite Particles

Imberg, Anna

January 2003

<p>A new kind of lipid/polymer composite particle, consisting of a biodegradable polymer matrix with well-defined lipid domains, has been created. The lipid used is the water-swelling lipid monoolein (MO), which forms a reversed bicontinuous cubic diamond structure in aqueous solutions. The polymer is poly(d,l-lactide-co-glycolide) (PLG), which degrades into water-soluble monomers through hydrolysis. This new particle might be a good alternative for encapsulation of active substances intended to be released over a longer period of time, i.e. sustained/retained/controlled release.</p><p>To prepare such particles can be difficult. Suitable phase behaviour and a solvent with the right properties are needed. For this reason, the phase behaviours of several different lipid/polymer/solvent/water systems have been explored. From the phase behaviour of a suitable system (i.e. MO/PLG/ethyl acetate/water), a route for formation of lipid/polymer composite particles has been deduced. Particles have been formed and distinct, water-swelling, lipid domains have been confirmed by characterization by means of confocal laser scanning probe microscopy (CLSM). </p><p>The sample preparation process has been automated and a method based on using a robotic liquid handler has been developed. Phase diagrams have been determined by examination of macroscopic behaviours and the microstructures of the phases have been studied by small- and wide-angle X-ray scattering (L₃, V₂, L_α, L), nuclear magnetic resonance self-diffusion (L, L₃), viscosimetry (L) and rheology (L). Several different theoretical models have been applied for interpretation of the results. For example, the swelling of the reversed bicontinuous cubic phases and the sponge phase have been modelled by applying the theory of infinite periodical minimal surfaces, the sponge phase has been shown to be bicontinuous according to the theory of interconnected rods and the phase behaviour of the polymer has been described by the Flory-Huggins theory. The main focus of this work (4/5) concerns phase studies in multicomponent systems from a physical-chemical point of view.</p>

Physical chemistry

Biodegradable

CLSM

Composite Particles

Controlled Release

Cubic Phases

Drug Delivery

Flory-Huggins Theory

FT-PGSE-NMR

IPMS

Liquid Phase

Lipid Domains

Liquid Handler

Microspheres

Microstructure

Phase Behaviour

Phase Separation

Polymer Matrix

SAXS

Segregation

Sponge Phase

Swelling

Fysikalisk kemi

Physical chemistry

Fysikalisk kemi

On Phase Behaviours in Lipid/Polymer/Solvent/Water Systems and their Application for Formation of Lipid/Polymer Composite Particles

Imberg, Anna

January 2003

A new kind of lipid/polymer composite particle, consisting of a biodegradable polymer matrix with well-defined lipid domains, has been created. The lipid used is the water-swelling lipid monoolein (MO), which forms a reversed bicontinuous cubic diamond structure in aqueous solutions. The polymer is poly(d,l-lactide-co-glycolide) (PLG), which degrades into water-soluble monomers through hydrolysis. This new particle might be a good alternative for encapsulation of active substances intended to be released over a longer period of time, i.e. sustained/retained/controlled release. To prepare such particles can be difficult. Suitable phase behaviour and a solvent with the right properties are needed. For this reason, the phase behaviours of several different lipid/polymer/solvent/water systems have been explored. From the phase behaviour of a suitable system (i.e. MO/PLG/ethyl acetate/water), a route for formation of lipid/polymer composite particles has been deduced. Particles have been formed and distinct, water-swelling, lipid domains have been confirmed by characterization by means of confocal laser scanning probe microscopy (CLSM). The sample preparation process has been automated and a method based on using a robotic liquid handler has been developed. Phase diagrams have been determined by examination of macroscopic behaviours and the microstructures of the phases have been studied by small- and wide-angle X-ray scattering (L3, V2, Lα, L), nuclear magnetic resonance self-diffusion (L, L3), viscosimetry (L) and rheology (L). Several different theoretical models have been applied for interpretation of the results. For example, the swelling of the reversed bicontinuous cubic phases and the sponge phase have been modelled by applying the theory of infinite periodical minimal surfaces, the sponge phase has been shown to be bicontinuous according to the theory of interconnected rods and the phase behaviour of the polymer has been described by the Flory-Huggins theory. The main focus of this work (4/5) concerns phase studies in multicomponent systems from a physical-chemical point of view.

Physical chemistry

Biodegradable

CLSM

Composite Particles

Controlled Release

Cubic Phases

Drug Delivery

Flory-Huggins Theory

FT-PGSE-NMR

IPMS

Liquid Phase

Lipid Domains

Liquid Handler

Microspheres

Microstructure

Phase Behaviour

Phase Separation

Polymer Matrix

SAXS

Segregation

Sponge Phase

Swelling

Fysikalisk kemi

Physical chemistry

Fysikalisk kemi