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Spectrin-lipid interactions and their effect on the membrane mechanical propertiesSarri, Barbara Claire Mireille Annick January 2014 (has links)
This thesis presents the experimental work performed on the spectrin protein. The aim of the work was to study the direct interactions of spectrin, the cytoskeleton of RBCs, with membrane lipid to determine its effects on the mechanical properties of the lipid bilayer. Motivation for this work came from a lack of unanimity in the field of spectrin, and the hypothesized potential of the protein to perforate giant unilamellar vesicles. The work aimed to investigate and determine how spectrin-lipid interactions influence membrane mesoscopic morphology and biophysics in ways that could ultimately be important to cellular function. For this purpose, a protocol was implemented to take into account the different aspects of the binding. Direct visualisation of the spectrin-lipid interaction and distribution was achieved using confocal fluorescence microscopy. Changes in the mechanical properties of the membrane were investigated using the micropipette aspiration technique. Finally the thermodynamics of the interaction were considered with isothermal titration calorimetry experiments. This allowed evaluation of the protein-lipid interaction in a complete and coherent manner. Experiments were also performed on another elastic protein, alpha-elastin, for comparison. In addition to its similarities with spectrin (both possess hydrophobic domains and entropy elasticity), elastin is auto-fluorescent which makes it an attractive model protein. Elastin was also used as a sample model to implement new techniques using nonlinear optics microscopy.
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GIANT UNILAMELLAR VESICLES FOR PEPTIDE-MEMBRANE INTERACTION STUDIES USING FLUORESCENCE MICROSCOPYNilsson, Martin January 2020 (has links)
Vesicles are a type of biological or biomimetic particle consisting of one or more often spherical bilayers made up of amphipathic molecules, creating a closed system. They can function as an encapsulating device, holding hydrophilic molecules on the inside of the bilayer membrane(s) or hydrophobic molecules in the non-polar interstitial space in the middle of the bilayers. Because of this capacity to carry molecules, vesicles are a premier system for drug delivery and even theranostics in vivo. A peptide-based approach to release of encapsulated molecules has previously been developed but since drug delivery vesicles are in the size range of nanometers, the mechanisms have not been visualized. This project aims to produce giant unilamellar vesicles as a model system used to visualize membrane interactions vital to the understanding and further development of smaller vesicle-based systems for drug delivery. Giant unilamellar vesicles were produced successfully and a preparation protocol was established. Additionally, some membrane interactions were investigated using fluorescence microscopy.
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Toca-1 driven actin polymerisation at membranesFox, Helen Mary January 2018 (has links)
Regulation of the actin cytoskeleton is key to cellular function and underlies processes including cell migration, mitosis and endocytosis. Motile cells send out dynamic actin protrusions that enable them to sense and interact with their environment, as well as generating physical forces. Linking of the actin cytoskeleton to the cell membrane is essential for the formation of these protrusions. The proteins that are thought to fulfil such a role have a membrane interacting domain (such as the PH domain in lamellipodin, or I-BAR protein in IRSp53) and a domain which interacts with actin regulatory proteins (such as the SH3 domain of IRSp53, which binds Ena and VASP). I investigated the contribution of the F-BAR protein Toca-1 in linking actin polymerisation to membranes, by characterising a new protein-protein interaction and the interaction of Toca-1 with giant unilamellar vesicles. FBP17, a homologue of Toca-1, can oligomerise to form 2D flat lattices and 3D tubules on membranes. Proteins of the Toca-1 family have previously been implicated in actin polymerisation in cell-free systems and during endocytosis. However, there is emerging evidence that Toca-1 family proteins could also be involved in the formation of outward facing protrusions, lamellipodia and filopodia. In an in vitro system that recapitulates the formation of filopodia-like structures (FLS) on supported lipid bilayers, Toca-1 is recruited early, suggesting a Toca-1 scaffolding mechanism could precede the recruitment of other actin regulators. One prediction of this model is that Toca-1 would bind proteins previously implicated in filopodia formation, such as formins. I found that extracts depleted of Toca-1 binding partners no longer forms filopodia-like structures and subsequently optimised pull-down assays to identify Toca-1 binding partners by mass-spectrometry. I identified four formins, Diaph1, Diaph3, FHOD1 and INF2, and as well as the actin elongation factors and filopodia proteins, Ena and VASP. I further characterised these interactions and found that Toca-1 binds Ena and VASP via its SH3 domain. The interaction is direct and is strongly reduced if the proline-rich region in Ena is deleted. VASP was still able to bind without its proline rich region, suggesting there could be additional binding sites. I discovered that the binding of Ena and VASP was dependent on the clustering state of Toca-1, whilst the binding of the previously identified Toca-1 binding partner N-WASP was not. This further supports the importance of Toca-1 oligomerisation in actin polymerisation. I tested these interactions in the FLS system and found that increasing Toca-1 concentration leads to increased recruitment of N-WASP, as well as the novel binding partner Ena to the structures, whereas an increase in VASP was not observed. SH3-domain mediated interactions are required for Toca-1 recruitment to FLS, suggesting that its membrane and protein binding activities act cooperatively. I showed that unlike N-WASP, which promotes the formation of branched actin, Ena and VASP are not required for actin polymerisation on supported lipid bilayers, suggesting that they are redundant with other factors in the elongation step of FLS formation. Ena and VASP are known to be important for the formation of neuronal filopodia and so I began to further test the role of these interactions in a cellular context using a neuronal cell culture system. As well as recruiting protein binding partners, F-BAR family proteins are implicated in stabilising lipid microdomains and can induce the clustering of phosphoinositides. I investigated the role of Toca-1 in actin polymerisation on PI(4,5)P2-rich giant unilamellar vesicles (GUVs). Actin-rich tails formed on the GUVs only when excess Toca-1 was supplemented into the extracts, and I propose that this is due to lipid organisation by Toca-1. In summary, my work suggests a model in which Toca-1 clusters, stabilises the membrane lipids and recruits regulators of actin polymerisation, such as Ena. This mechanism could be used to link actin polymerisation to the membrane in cellular protrusions, such as filopodia.
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Estudo de propriedades biofísicas de membrana sob estresse oxidativo e a interação com proteínas formadoras de poros / Study of biophysical properties in membranes under oxidative stress and interaction with pore-forming proteinsChecchia, Robert Garcia 12 February 2019 (has links)
Neste trabalho investigamos efeitos de fotoirradiação e toxinas sob membranas celulares miméticas. Foram utilizadas, como modelo de membranas lipídicas, vesiculas unilamelares gigantes (GUVs) compostas pro lipídeos oxidados e não oxidados observadas por microscopia ótica de contraste de fase. Inicialmente estudamos a foto-resposta de membranas compostas por POPC e POPG dispersas em solução contendo azul de metileno (MB). Na sequência, estudamos o efeito de toxinas formadoras de poros, Esticolisina I (ST I) e Esticolisina II (ST II), em membranas contendo lipídeos oxidados e não oxidados. Os resultados de MB (10 µM) disperso em solução de membranas compostas por POPC e o lipídeo aniônico POPG indicaram que o aumento da densidade de carga negativa nas membranas das GUVs, que favorece a ligação da moléculas positivamente carregadas como MB nas membranas, tem como consequência um aumento de permeabilidade da membrana muito mais rápído em relação a membranas compostas apenas por POPC. Isto se deve ao fato que a localização preferencial do MB na membrana de POPC:POPG favorece a formação de oxigênio singlete próximo a dupla ligação da cadeia alquílica, dando início a reação de peroxidação lipídica de maneira mais efetiva que em membrana de POPC. Os resultados da ação das toxinas STI e STII (21 nM) em GUVs contendo lipídeos não oxidados PC e esfingomielina evidenciam que apenas STII é capaz de permear estas membranas a esta concentração. Mais ainda, nossos resultados sugerem que a existência de separação de fases fluida-gel na bicamada lipidica composta por PC:SM (razão molar 1:1) favorece a ação da toxina StII. Ao analisarmos membranas contendo lipídeos hidroperoxidados (POPC-OOH) dispersas em solução contendo STII (21 nM) observamos um aumento de permeabilidade na membrana num conjunto de GUVs, associado a formação de poros, apenas em bicamadas lipídicas formadas por misturas de lipídeos oxidados (POPC) e não oxidados (POPC-OOH). Quanto maior a concentração de lipídeos oxidados na membrana mais rapidamente ocorre o aumento de permeabilidade. / In this work we investigate the effects of photoirradiation and toxins on mimetic cell membranes. As a model of lipid membranes, giant unilamellar vesicles (GUVs) composed of oxidized and oxidized pro-lipids were observed by optical phase contrast microscopy. Initially we studied the photo-response of membranes composed of POPC and POPG dispersed in solution containing methylene blue (MB). Following, we studied the effect of pore-forming toxins, Sticolysin I (ST I) and Sticolysin II (ST II), on membranes containing oxidized and non-oxidized lipids. The results of MB (10 M) dispersed in solution of membranes composed of POPC and the anionic lipid POPG indicated that the increase in the negative charge density in the membranes of GUVs, which favors the binding of positively charged molecules as MB in the membranes, consequently increases membrane permeability in regard to membranes composed only of POPC. This is due to the fact that the preferred location of the MB in the POPC: POPG membrane favors the formation of singlet oxygen near the double bond of the alkyl chain, initiating the lipid peroxidation reaction more effectively than in the POPC membrane. The results of the action of the STI and STII toxins (21 nM) on GUVs containing non oxidised lipids PC and sphingomyelin show that only STII is able to permeate these membranes at this concentration. Moreover, our results suggest that the existence of fluid-gel phase separation in the lipid bilayer composed of PC:SM (molar ratio 1:1) favors the action of the StII toxin. When analyzing membranes containing hydroperoxidized lipids (POPC-OOH) dispersed in solution containing STII (21 nM) we observed an increase in membrane permeability in a set of GUVs, associated with pore formation, only in lipid bilayers formed by mixtures of oxidized lipids (POPC-OOH) and non-oxidized ones. The higher the concentration of oxidized lipids in the membrane, the faster the permeability increases.
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Giant vesiclesStöckl, Martin Thomas 14 January 2009 (has links)
In der vorliegenden Arbeit wird ein neuer Ansatz vorgestellt, um Lipiddomänen, die Bindungsorte peripherer und integraler Membranproteine darstellen können, zu charakterisieren. Insbesondere wurde die Analyse der Fluoreszenzlebenszeiten von NBD-markierten Lipidanaloga benutzt, um Lipiddomänen in Giant unilamellar vesicles (GUV) und darauf aufbauend, in der Plasmamembran von Säugerzellen zu untersuchen. Das typische Zeitfenster von Fluoreszenzlebenszeiten im Bereich von Nanosekunden ermöglicht es, auch sehr kurzlebige Lipiddomänen nachzuweisen. Mit Hilfe des Fluorescence lifetime imaging (FLIM) wurden für die liquid disordered (ld) und liquid ordered (lo) Domänen in GUV jeweils spezifische Werte für das Abklingen der Fluoreszenz gemessen. Sogar die Existenz von submikroskopischen Domänen in GUV konnte nachgewiesen werden. Die Fluoreszenzlebenszeit des Lipidanalogs C6-NBD-PC zeigte in der Plasmamembran von Säugerzellen eine breite Verteilung. Dies legt in Übereinstimmung mit FLIM-Experimenten an aus der Plasmamembran von HeLa-Zellen gewonnenen Giant vesicles nahe, dass in der Plasmamembran von Zellen eine Vielzahl verschiedener submikroskopischer Lipiddomänen existiert. Darauf aufbauend wurde die Fluoreszenzmikroskopie an GUV angewendet, um die Bindung von fluoreszenzmarkiertem alpha-Synuclein an mittels FLIM charakterisierte Lipiddomänen zu untersuchen. Die Experimente zeigten, dass das Protein mit hoher Affinität an negativ geladene Phospholipide unter der Vorraussetzung bindet, dass diese sich in ld Domänen befinden. Im Gegensatz dazu erfolgt keine Bindung wenn diese Lipide in lo Domänen lokalisiert sind. Im Vergleich zum wildtypischen alpha-Synuclein zeigte die Variante A30P eine geringere Affinität zur Membran, während die E46K-Variante eine stärkere Bindung zeigte. Dies deutet darauf hin, dass bei den erblichen Formen des Morbus Parkinson eine veränderte Assoziation des alpha-Synucleins mit der Membran eine Rolle spielen kann. / In the present study a novel approach to characterize lipid domains, which may provide binding sites for peripheral or integral membrane proteins, is demonstrated. In particular, analysis of fluorescence lifetimes of NBD-labeled lipid analogues was used to study lipid domains in Giant unilamellar vesicles (GUV) and – based on the GUV results – in the plasma membrane of mammalian cells. As fluorescence decays in a few nanoseconds it is possible to to detect also very short-lived lipid domains. Fluorescence Lifetime Imaging (FLIM) revealed that the fluorescence decay of NBD-lipid analogues showed domain dependent decay times in the liquid disordered (ld) and the liquid ordered (lo) phase of GUV. Even the existence of submicroscopic domains in lipid membranes could be detected by FLIM. A broad distribution of the fluorescence lifetime was found for C6-NBD-PC inserted in the plasma membrane of mammalian cells. In agreement with FLIM studies on lipid domain forming Giant vesicles derived from the plasma membrane of HeLa-cells this may suggest that a variety of submicroscopic lipid domains exists in the plasma membrane of intact mammalian cells. Based on that, fluorescence microscopy was used on GUV to study the binding of fluorescently labeled alpha-synuclein at lipid domains previously characterized by FLIM. The experiments suggested that alpha-synuclein binds with high affinity to negatively charged phospholipids, when they are embedded in a ld as opposed to a lo environment. When compared with wildtype alpha-synuclein, the disease-causing alpha-synuclein variant A30P bound less efficiently to anionic phospholipids, while the variant E46K showed enhanced binding. This suggests that an altered association of alpha-synuclein with membranes may play a role in the inherited forms of Parkinson’s disease.
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Estudo de propriedades biofísicas de membrana sob estresse oxidativo e a interação com proteínas formadoras de poros / Study of biophysical properties in membranes under oxidative stress and interaction with pore-forming proteinsRobert Garcia Checchia 12 February 2019 (has links)
Neste trabalho investigamos efeitos de fotoirradiação e toxinas sob membranas celulares miméticas. Foram utilizadas, como modelo de membranas lipídicas, vesiculas unilamelares gigantes (GUVs) compostas pro lipídeos oxidados e não oxidados observadas por microscopia ótica de contraste de fase. Inicialmente estudamos a foto-resposta de membranas compostas por POPC e POPG dispersas em solução contendo azul de metileno (MB). Na sequência, estudamos o efeito de toxinas formadoras de poros, Esticolisina I (ST I) e Esticolisina II (ST II), em membranas contendo lipídeos oxidados e não oxidados. Os resultados de MB (10 µM) disperso em solução de membranas compostas por POPC e o lipídeo aniônico POPG indicaram que o aumento da densidade de carga negativa nas membranas das GUVs, que favorece a ligação da moléculas positivamente carregadas como MB nas membranas, tem como consequência um aumento de permeabilidade da membrana muito mais rápído em relação a membranas compostas apenas por POPC. Isto se deve ao fato que a localização preferencial do MB na membrana de POPC:POPG favorece a formação de oxigênio singlete próximo a dupla ligação da cadeia alquílica, dando início a reação de peroxidação lipídica de maneira mais efetiva que em membrana de POPC. Os resultados da ação das toxinas STI e STII (21 nM) em GUVs contendo lipídeos não oxidados PC e esfingomielina evidenciam que apenas STII é capaz de permear estas membranas a esta concentração. Mais ainda, nossos resultados sugerem que a existência de separação de fases fluida-gel na bicamada lipidica composta por PC:SM (razão molar 1:1) favorece a ação da toxina StII. Ao analisarmos membranas contendo lipídeos hidroperoxidados (POPC-OOH) dispersas em solução contendo STII (21 nM) observamos um aumento de permeabilidade na membrana num conjunto de GUVs, associado a formação de poros, apenas em bicamadas lipídicas formadas por misturas de lipídeos oxidados (POPC) e não oxidados (POPC-OOH). Quanto maior a concentração de lipídeos oxidados na membrana mais rapidamente ocorre o aumento de permeabilidade. / In this work we investigate the effects of photoirradiation and toxins on mimetic cell membranes. As a model of lipid membranes, giant unilamellar vesicles (GUVs) composed of oxidized and oxidized pro-lipids were observed by optical phase contrast microscopy. Initially we studied the photo-response of membranes composed of POPC and POPG dispersed in solution containing methylene blue (MB). Following, we studied the effect of pore-forming toxins, Sticolysin I (ST I) and Sticolysin II (ST II), on membranes containing oxidized and non-oxidized lipids. The results of MB (10 M) dispersed in solution of membranes composed of POPC and the anionic lipid POPG indicated that the increase in the negative charge density in the membranes of GUVs, which favors the binding of positively charged molecules as MB in the membranes, consequently increases membrane permeability in regard to membranes composed only of POPC. This is due to the fact that the preferred location of the MB in the POPC: POPG membrane favors the formation of singlet oxygen near the double bond of the alkyl chain, initiating the lipid peroxidation reaction more effectively than in the POPC membrane. The results of the action of the STI and STII toxins (21 nM) on GUVs containing non oxidised lipids PC and sphingomyelin show that only STII is able to permeate these membranes at this concentration. Moreover, our results suggest that the existence of fluid-gel phase separation in the lipid bilayer composed of PC:SM (molar ratio 1:1) favors the action of the StII toxin. When analyzing membranes containing hydroperoxidized lipids (POPC-OOH) dispersed in solution containing STII (21 nM) we observed an increase in membrane permeability in a set of GUVs, associated with pore formation, only in lipid bilayers formed by mixtures of oxidized lipids (POPC-OOH) and non-oxidized ones. The higher the concentration of oxidized lipids in the membrane, the faster the permeability increases.
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Structure and Mechanics of Neuronal Model Systems / Insights from Atomic Force Microscopy and Micropipette AspirationVache, Marian 09 April 2019 (has links)
No description available.
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Combining artificial Membrane Systems and Cell Biology Studies: New Insights on Membrane Coats and post-Golgi Carrier FormationStange, Christoph 16 January 2013 (has links) (PDF)
In mammalian cells, homeostasis and fate during development relies on the proper transport of membrane-bound cargoes to their designated cellular locations. The hetero-tetrameric adaptor protein complexes (APs) are required for sorting and concentration of cargo at donor membranes, a crucial step during targeted transport. AP2, which functions at the plasma membrane during clathrin-mediated endocytosis, is well characterized. In contrast, AP1 a clathrin adaptor mediating the delivery of lysosomal hydrolases via mannose 6-phosphate receptors (MPRs) and AP3 an adaptor ensuring the proper targeting of lysosomal membrane protein are difficult to study by classic cell biology tools. To gain new insights on these APs, our lab has previously designed an in vitro system. Reconstituted liposomes were modified with small peptides mimicking the cytosolic domains of bona fide cargoes for AP1 and AP3 respectively and thereby enabling the selective recruitment of these APs and the identification of the interacting protein network.
In the study at hand we utilize above-described liposomes to generate supported lipid bilayers and Giant Unilamellar Vesicles (GUVs), large-scale membrane systems suited for analysis by fluorescence microscopy. By using cytosol containing fluorescently-tagged subunits, we visualized clathrin coats on artificial membranes under near physiological conditions for the first time. Moreover, we demonstrated clathrin-independent recruitment of AP3 coats on respective GUVs. Presence of active ARF1 was sufficient for the selective assembly of AP1-dependent clathrin coats and AP3 coats on GUVs. By using dye-conjugated ARF1, we show that ARF1 colocalized with AP3 coats on GUVs and that increased association of ARF1 with GUVs coincided with AP1-dependent clathrin coats.
Our previous study identified members of the septin family together with AP3 coats on liposomes. Here we show on GUVs, that active ARF1 stimulated the assembly of septin7 filaments, which may constrain the size and mobility of AP3 coats on the surface. Subsequent cell biology studies in HeLa cells linked septins to actin fibers on which they may control mobility of AP3-coated endosomes and thus their maturation. An actin nucleation complex, based on CYFIP1 was identified together with AP1 on liposomes before. Here we show on GUVs, that CYFIP1 is recruited on the surface surrounding clathrin coats. Upon supply of ATP, sustained actin polymerization generated a thick shell of actin on the GUV surface. The force generated by actin assembly lead to formation of long tubular protrusions, which projected from the GUV surface and were decorated with clathrin coats. Thereby the GUV model illustrated a possible mechanism for tubular carriers formation. The importance of CYFIP1-reliant actin polymerization for the generation of MPR-positive tubules at the trans-Golgi network (TGN) of HeLa cells was subsequently demonstrated in our lab.
The notion that tubulation of artificial membranes could be triggered by actin polymerization allowed us to perform a comparative mass spectrometry screen. By comparing the abundance of proteins on liposomes under conditions promoting or inhibiting actin polymerization, candidates possibly involved in stabilization, elongation or fission of membrane tubules could be identified.
Among the proteins enriched under conditions promoting tubulation, we identified type I phosphatidylinositol-4-phosphate 5-kinases. Their presence suggested an involvement of phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2) in tubule formation. By cell biology studies in HeLa we show, that down regulation of these enzymes altered the dynamics of fluorescently-tagged MPRs, illustrating the importance of locally confined PI(4,5)P2 synthesis during formation of coated carriers at the TGN.
Bin–Amphiphysin–Rvs (BAR) domains are known to sense membrane curvature and induce membrane tubulation. Among various BAR domain proteins, Arfaptin2 was enriched under conditions allowing tubulation of liposomes. By microscopy studies on HeLa cells we show, that Arfaptin2 as well as its close paralog Arfaptin1 were present on AP1-coated MPR tubules emerging from the TGN. We further show, that tubule fission occurred at regions were Arfaptin1 is concentrated and that simultaneous down regulation of both Arfaptins lead to increased number and length of MPR tubules. Since fission of coated transport intermediates at the TGN is poorly understood, our findings contribute a valuable component towards a model describing the entire biogenesis of coated post-Golgi carriers. In conclusion, combining artificial membrane systems and cell biology studies allowed us to propose new models for formation as wall as for fission of AP1-coated transport intermediates at the TGN. Further we gained new insights on AP3 coats and the possible involvement of septin filaments in AP3-dependent endosomal maturation.
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Combining artificial Membrane Systems and Cell Biology Studies: New Insights on Membrane Coats and post-Golgi Carrier FormationStange, Christoph 13 December 2012 (has links)
In mammalian cells, homeostasis and fate during development relies on the proper transport of membrane-bound cargoes to their designated cellular locations. The hetero-tetrameric adaptor protein complexes (APs) are required for sorting and concentration of cargo at donor membranes, a crucial step during targeted transport. AP2, which functions at the plasma membrane during clathrin-mediated endocytosis, is well characterized. In contrast, AP1 a clathrin adaptor mediating the delivery of lysosomal hydrolases via mannose 6-phosphate receptors (MPRs) and AP3 an adaptor ensuring the proper targeting of lysosomal membrane protein are difficult to study by classic cell biology tools. To gain new insights on these APs, our lab has previously designed an in vitro system. Reconstituted liposomes were modified with small peptides mimicking the cytosolic domains of bona fide cargoes for AP1 and AP3 respectively and thereby enabling the selective recruitment of these APs and the identification of the interacting protein network.
In the study at hand we utilize above-described liposomes to generate supported lipid bilayers and Giant Unilamellar Vesicles (GUVs), large-scale membrane systems suited for analysis by fluorescence microscopy. By using cytosol containing fluorescently-tagged subunits, we visualized clathrin coats on artificial membranes under near physiological conditions for the first time. Moreover, we demonstrated clathrin-independent recruitment of AP3 coats on respective GUVs. Presence of active ARF1 was sufficient for the selective assembly of AP1-dependent clathrin coats and AP3 coats on GUVs. By using dye-conjugated ARF1, we show that ARF1 colocalized with AP3 coats on GUVs and that increased association of ARF1 with GUVs coincided with AP1-dependent clathrin coats.
Our previous study identified members of the septin family together with AP3 coats on liposomes. Here we show on GUVs, that active ARF1 stimulated the assembly of septin7 filaments, which may constrain the size and mobility of AP3 coats on the surface. Subsequent cell biology studies in HeLa cells linked septins to actin fibers on which they may control mobility of AP3-coated endosomes and thus their maturation. An actin nucleation complex, based on CYFIP1 was identified together with AP1 on liposomes before. Here we show on GUVs, that CYFIP1 is recruited on the surface surrounding clathrin coats. Upon supply of ATP, sustained actin polymerization generated a thick shell of actin on the GUV surface. The force generated by actin assembly lead to formation of long tubular protrusions, which projected from the GUV surface and were decorated with clathrin coats. Thereby the GUV model illustrated a possible mechanism for tubular carriers formation. The importance of CYFIP1-reliant actin polymerization for the generation of MPR-positive tubules at the trans-Golgi network (TGN) of HeLa cells was subsequently demonstrated in our lab.
The notion that tubulation of artificial membranes could be triggered by actin polymerization allowed us to perform a comparative mass spectrometry screen. By comparing the abundance of proteins on liposomes under conditions promoting or inhibiting actin polymerization, candidates possibly involved in stabilization, elongation or fission of membrane tubules could be identified.
Among the proteins enriched under conditions promoting tubulation, we identified type I phosphatidylinositol-4-phosphate 5-kinases. Their presence suggested an involvement of phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2) in tubule formation. By cell biology studies in HeLa we show, that down regulation of these enzymes altered the dynamics of fluorescently-tagged MPRs, illustrating the importance of locally confined PI(4,5)P2 synthesis during formation of coated carriers at the TGN.
Bin–Amphiphysin–Rvs (BAR) domains are known to sense membrane curvature and induce membrane tubulation. Among various BAR domain proteins, Arfaptin2 was enriched under conditions allowing tubulation of liposomes. By microscopy studies on HeLa cells we show, that Arfaptin2 as well as its close paralog Arfaptin1 were present on AP1-coated MPR tubules emerging from the TGN. We further show, that tubule fission occurred at regions were Arfaptin1 is concentrated and that simultaneous down regulation of both Arfaptins lead to increased number and length of MPR tubules. Since fission of coated transport intermediates at the TGN is poorly understood, our findings contribute a valuable component towards a model describing the entire biogenesis of coated post-Golgi carriers. In conclusion, combining artificial membrane systems and cell biology studies allowed us to propose new models for formation as wall as for fission of AP1-coated transport intermediates at the TGN. Further we gained new insights on AP3 coats and the possible involvement of septin filaments in AP3-dependent endosomal maturation.
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Systèmes modèles de membranes et potentiel de pénétration de polypeptides / Model lipid systems and their interactions with polypeptidesWeinberger, Andreas 30 September 2013 (has links)
Les vésicules géantes unilamellaires (GUV) permettent d’étudier efficacement les interactions entre les lipides et les peptides. Dans ce manuscrit, il a été montré que les interactions attractives lipides-peptides sont supprimées par l’attachement de polypeptides de type élastine (ELP) sur des peptides riches en arginine et peuvent être modulées par l’auto-assemblage en micelles ainsi que par le nombre de groupements arginine dans la séquence des peptides capables de pénétrer les cellules. De plus, une nouvelle méthode pour former des GUV à partir de systèmes complexes en seulement quelques minutes a été développée. Cette méthode est basée sur le gonflement d’un film de PVA sous une bicouche lipidique. Elle supprime la dégradation des molécules pendant la formation des GUV de lipides synthétiques, tels que des glycolipides et des phospholipides portant des groupements amides, où les méthodes traditionnelles ne réussissent pas à produire des vésicules non endommagées. / Giant Unilamellar Vesicles (GUVs) are a valuable tool to study lipid bilayer-biomolecule interactions in simplified cell-like model systems. In this work, a new method to efficiently form GUVs within minutes from more complex systems was developed. This method is based on swelling of a PVA-film under a lipid bilayer and minimizes damage of involved molecules during GUV formation. It also opens up many interesting perspectives for the formation of GUVs composed from new classes of synthetic lipids, such as glycolipids and amide-bearing phospholipids, where the traditional methods fail to efficiently produce “undamaged” vesicles. GUVs were also used for studying lipid-peptide interactions of a new class of elastin-like polypeptides functionalized with arginine-rich residues. It is shown that attractive interactions between lipids and peptides are suppressed by cargo-attachment and can be tuned by self-assembly into micelles and the arginine-amount of the cell penetrating residue.
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