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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Development of New Supported Bilayer Platforms for Membrane Protein Incorporation

Mulligan, Kirk M. 15 April 2013 (has links)
Membranes are essential components of all living organisms forming the borders of cells and their organelles. Planar lipid membranes deposited on solid substrates (solid supported membranes) provide models to study the functions of membrane proteins and are used as biosensing platforms. However, despite remarkable progress, solid supported membranes are not stable to harsh conditions such as dehydration, high temperature and pressure, and mechanical stress. In addition, the direct deposition of membranes onto a solid substrate often causes restricted mobility and denaturation of reconstituted membrane proteins. Membrane stability can be addressed by altering the structure of the component lipids. Bolalipids are an interesting class of bipolar lipids that have been proposed for biosensing applications. Membranes formed from mixtures of a bolalipid, C20BAS, and dioleoylphosphaphatidylcholine, POPC, were characterized by atomic force spectroscopy (AFM). The lipid mixtures produced a phase separated membrane consisting of thinner bolalipid-rich and thicker monopolar-rich POPC regions, with a height difference of approximately 1-2 nm. This confirmed an earlier prediction that some bolalipid/PC membranes would phase separate due to the hydrophobic mismatch between the two lipids. Interestingly, the surface coverage of the two phases was inconsistent with what one would expect from the initial starting lipid ratios. The complex membrane morphologies observed were accredited to the interplay of several factors, including a compositionally heterogeneous vesicle population, exchange of lipid between the vesicle solution and solid substrate during formation of the supported membrane, and slow equilibration of domains due to pinning of the lipids to the solid support. Decoupling the membrane from its underlying surface is one strategy to maintain the structure and mobility of membrane proteins. This decoupling can be achieved by depositing the membrane on a soft cushion composed of a water swelling hydrophilic polymer. A polyelectrolyte multilayer (PEM) and a tethered poly(ethylene) glycol (PEG) polymer are the two types of polymer cushions used in this study. The PEMs consist of the charged polysaccharides, chitosan (CHI) and hyaluronic acid (HA) which offer the advantage of biocompatibility over synthetic PEMs. DOPC lipid bilayers were formed at pH 4 and 6.5 on (CHI/HA)5 films. At higher pH adsorbed lipids had low mobility and large immobile lipid fractions; fluorescence and AFM showed that this was accredited to the formation of poor quality membranes with defects and pinned lipids rather than to a layer of surface-adsorbed vesicles. However, more uniform bilayers with mobile lipids were produced at pH 4. Measured diffusion coefficients were similar to those for bilayers on PEG cushions and considerably higher than those measured on other polyelectrolyte films. The results suggest that the polymer surface charge is more important than the surface roughness in controlling formation of mobile supported bilayers. The suitability of polymer supported membranes for the incorporation of integral membrane proteins was also assessed. The integral membrane protein Ste14p, a 26 kDa methyltransferase enzyme, was reconstituted into POPC membranes on PEM and PEG supports. A combination of fluorescence microscopy, FRAP, AFM and an in situ methyltransferase activity assay were utilized to characterize the protein incorporated polymer supported membranes. Fluorescence measurements showed that more protein was incorporated in model membranes formed on the PEG support, compared to either glass or PEM cushions. However, the protein activity on a PEG support was comparable to that of the protein in a membrane on glass. FRAP measurements showed that the lipid mobilities of the POPC:Ste14p bilayers on the various supports were also comparable. Lastly, as a new platform for manipulating and handling membrane proteins, nanodiscs containing reconstituted Ste14p were studied. Nanodiscs are small, soluble and stable bilayer discs that permit the study of membrane proteins in a uniform phospholipid bilayer environment. Empty and protein containing nanodiscs were deposited on a mica surface and imaged by AFM. AFM showed that protein containing samples possessed two subpopulations of nanodiscs with a height difference of ~1 nm. The taller discs, ~20% of the population, contained protein. Other experiments showed that the packing of the nanodisc samples was influenced by their initial stock concentration and that both imaging force and the addition of Mg2+ caused formation of larger bilayer patches.
2

Development of New Supported Bilayer Platforms for Membrane Protein Incorporation

Mulligan, Kirk M. January 2013 (has links)
Membranes are essential components of all living organisms forming the borders of cells and their organelles. Planar lipid membranes deposited on solid substrates (solid supported membranes) provide models to study the functions of membrane proteins and are used as biosensing platforms. However, despite remarkable progress, solid supported membranes are not stable to harsh conditions such as dehydration, high temperature and pressure, and mechanical stress. In addition, the direct deposition of membranes onto a solid substrate often causes restricted mobility and denaturation of reconstituted membrane proteins. Membrane stability can be addressed by altering the structure of the component lipids. Bolalipids are an interesting class of bipolar lipids that have been proposed for biosensing applications. Membranes formed from mixtures of a bolalipid, C20BAS, and dioleoylphosphaphatidylcholine, POPC, were characterized by atomic force spectroscopy (AFM). The lipid mixtures produced a phase separated membrane consisting of thinner bolalipid-rich and thicker monopolar-rich POPC regions, with a height difference of approximately 1-2 nm. This confirmed an earlier prediction that some bolalipid/PC membranes would phase separate due to the hydrophobic mismatch between the two lipids. Interestingly, the surface coverage of the two phases was inconsistent with what one would expect from the initial starting lipid ratios. The complex membrane morphologies observed were accredited to the interplay of several factors, including a compositionally heterogeneous vesicle population, exchange of lipid between the vesicle solution and solid substrate during formation of the supported membrane, and slow equilibration of domains due to pinning of the lipids to the solid support. Decoupling the membrane from its underlying surface is one strategy to maintain the structure and mobility of membrane proteins. This decoupling can be achieved by depositing the membrane on a soft cushion composed of a water swelling hydrophilic polymer. A polyelectrolyte multilayer (PEM) and a tethered poly(ethylene) glycol (PEG) polymer are the two types of polymer cushions used in this study. The PEMs consist of the charged polysaccharides, chitosan (CHI) and hyaluronic acid (HA) which offer the advantage of biocompatibility over synthetic PEMs. DOPC lipid bilayers were formed at pH 4 and 6.5 on (CHI/HA)5 films. At higher pH adsorbed lipids had low mobility and large immobile lipid fractions; fluorescence and AFM showed that this was accredited to the formation of poor quality membranes with defects and pinned lipids rather than to a layer of surface-adsorbed vesicles. However, more uniform bilayers with mobile lipids were produced at pH 4. Measured diffusion coefficients were similar to those for bilayers on PEG cushions and considerably higher than those measured on other polyelectrolyte films. The results suggest that the polymer surface charge is more important than the surface roughness in controlling formation of mobile supported bilayers. The suitability of polymer supported membranes for the incorporation of integral membrane proteins was also assessed. The integral membrane protein Ste14p, a 26 kDa methyltransferase enzyme, was reconstituted into POPC membranes on PEM and PEG supports. A combination of fluorescence microscopy, FRAP, AFM and an in situ methyltransferase activity assay were utilized to characterize the protein incorporated polymer supported membranes. Fluorescence measurements showed that more protein was incorporated in model membranes formed on the PEG support, compared to either glass or PEM cushions. However, the protein activity on a PEG support was comparable to that of the protein in a membrane on glass. FRAP measurements showed that the lipid mobilities of the POPC:Ste14p bilayers on the various supports were also comparable. Lastly, as a new platform for manipulating and handling membrane proteins, nanodiscs containing reconstituted Ste14p were studied. Nanodiscs are small, soluble and stable bilayer discs that permit the study of membrane proteins in a uniform phospholipid bilayer environment. Empty and protein containing nanodiscs were deposited on a mica surface and imaged by AFM. AFM showed that protein containing samples possessed two subpopulations of nanodiscs with a height difference of ~1 nm. The taller discs, ~20% of the population, contained protein. Other experiments showed that the packing of the nanodisc samples was influenced by their initial stock concentration and that both imaging force and the addition of Mg2+ caused formation of larger bilayer patches.
3

Formation of polymer lipid nanodiscs for membrane protein studies

Tognoloni, Cecilia January 2017 (has links)
No description available.
4

A new model of lipidated apoE provided by chemical cross-linking/mass spectrometry and in silico modeling

Henry, Nicolas 21 November 2014 (has links)
Apolipoprotein E (apoE) is crucial for lipid transport and cholesterol homeostasis within the plasma and central nervous system. Binding to lipoprotein particles activates apoE allowing it to interact with cell surface receptors such as the low density lipoprotein receptor (LDLr). This mediates the clearance of apoE containing lipoproteins through an endocytosis pathway and therefore reduces plasma cholesterol level, explaining the strong anti-atherogenic effect of apoE. Nevertheless, the active conformation of apoE, critical for the receptor interaction, remains elusive. Since high resolution structure-determination methods (i.e. NMR and X-ray crystallography) are not yet applicable to large protein/lipid complexes, we are actually in need of biophysical techniques to solve the structure-activity relationship of lipidated apoE. The aim of this work was to elucidate the lipidated structure of apoE. Therefore, we reconstituted apoE/lipid particles mimicking a subspecies of high density lipoproteins (HDL) found in the plasma, starting from recombinant apoE and synthetic lipids (POPC). After optimization, a homogeneous population of reconstituted apoE/POPC lipoproteins was obtained. A thorough characterization by different biochemical methods (native PAGE, electron microscopy, FTIR…) showed that these lipoprotein particles bear 2 apoE molecules at their surface and display a discoidal shape with a diameter of 105Å. Further structural information was gathered by using a combination of lysine-directed cross-linking and mass spectrometry. We then developed a two-step modeling procedure using all the structural knowledge acquired at this point enriched with literature data to build 3D atomic resolution structural models of the apoE4/POPC complexes. First, monomeric apoE models were produced in the absence of lipids using a distance calculation program. These initial models, where apoE is folded into a helical hairpin, should reflect the conformation adopted by the protein on a disc-shaped lipoprotein. Secondly, two modeled monomeric conformations were dimerized, associated with a lipid disc, solvated and finally subjected to a molecular dynamics (MD) simulation. Our MD trajectories show an elongation of a helix in the N-terminal domain that redefines the position of Arg172, a key residue for LDLr binding, in regards to the well-defined receptor binding region (residues 136-150) of apoE. The observed elongation explains why the lipidation of apoE is an essential requirement in the activation mechanism and offers an ideal framework for the recognition of two specific LDLr ligand binding repeats needed for full binding to the LDLr. Based on an important structural change observed in our different models, we can also propose an activation mechanism relying on a regulation of the accessibility of the ligand binding region by the protein itself. Thus, the two new presented models provide important structural information at the atomic level and new insights into the mechanisms involved in apoE receptor recognition. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
5

Structural studies of HDL and applications of EM on membrane proteins

Zhu, Lin January 2017 (has links)
A large number of proteins interact with biological membranes, either integrated in the membrane (PepTSo2), embedded on a membrane surface (5-lipoxygenase) or encircling a cutout of lipid bilayer (apolipoprotein1 (apoA-I). They function as transporters, receptors or biocatalysts in cellular processes like inflammation or cholesterol transport which are touched upon here. Malfunction of specific membrane proteins are the cause for several diseases or disorders. Knowledge of protein structure supports understanding of its mechanism of function. Here, transmission electron microscopy (TEM) was used for structure determination. To obtain structure information to high resolution for membrane proteins, normally surrounded by lipids, demands specific methods and materials for stabilization. Stabilized in detergent the structure of the bacterial transporter PepTSo2 was shown to form a tetramer even bound to substrate. However, with a protein based stabilizer, Salipro, the structure of PepTSo2 could be determined to high resolution. High density lipoprotein (HDL) in blood plasma, involved in the removal of cholesterol from peripheral tissues, have a central role in cardiovascular function, metabolic syndrome and diabetes. The HDL-particle is composed of two copies of ApoA1 and around hundred lipid molecules. From TEM data, for the first time the clearly discoidal shape could be shown by 3-dimendional reconstructions. These were used for modelling the ApoA1 protein dimer by a "biased fitting" procedure. The results indicate how ApoA1 folds around a lipid bilayer in a disc-shaped structure. Modified HDL called nanodiscs were here used to show the Ca2+ dependent binding of 5-lipoxygenase on the nanodisc bilayer and thereby increased production of the inflammatory mediator leukotrieneA4. Dimerization of 5-lipoxygenase inactivates these functions. / <p>QC 20170323</p>
6

Influence of lipid membrane environment on the kinetics of the cytochrome P450 reductase- cytochrome P450 3A4 enzyme system in nanodiscs

Liu, Kang-Cheng January 2017 (has links)
The cytochrome P450 enzyme system is a multicomponent electron-transfer chain composed of a haem-containing monooxygenase cytochrome P450 (CYP) and one or more redox partners. Eukaryotic CYPs and their redox partner NADPH-dependent cytochrome P450 oxidoreductase (CPR) are involved in many biological processes. Each protein has one N- terminal membrane anchor domain for location within the endoplasmic reticulum (ER). In mammals, CYPs and CPR are especially abundant in liver cells, where they play important roles in the metabolism of steroids, fatty acids, and xenobiotic compounds including numerous drugs of pharmaceutical importance. Incorporation into lipid membranes is an important aspect of CYP and CPR function, influencing their kinetic properties and interactions. In this thesis, soluble nanometer-scale phospholipid bilayer membrane discs, "nanodiscs", were used as a reconstitution system to study the influence of lipid membrane composition on the activities of the abundant human CYP3A4 and human CPR. Both enzymes were expressed and purified from bacteria, and assembled into functionally active membrane-bound complexes in nanodiscs. Nanodisc assembly was assessed by a combination of native and denaturing gel electrophoresis, and a fluorimetric assay was developed to study CYP3A4 reaction kinetics using 7-benzyloxyquinoline as substrate. Kinetic properties were investigated with respect to different lipid membrane compositions: phosphatidyl choline; a synthetic lipid mixture resembling the ER; and natural lipids extracted from liver microsomes. Full activity of the CYP3A4 system, with electron transfer from NADPH via CPR, could only be reconstituted when both CYP3A4 and CPR were membrane-bound within the same nanodiscs. No activity was observed when CPR and CYP3A4 were each incorporated seperately into naodiscs then mixed together, or when soluble forms of CPR were mixed with pre-assembled CYP3A4-nanodiscs. Thus, assembly of the two proteins within the same membrane was shown to be essential for the function of the CPR-CYP3A4 electron transfer system. Comparison of the reaction kinetics in different membrane compositions revealed liver microsomal lipid to have an enhancing effect both on the activity of the assembled CPR-CYP3A4 nanodisc complex, and on the activity of CPR alone incorporated in nanodiscs, when compared either to the synthetic lipid mixture or to phosphatidyl choline alone. Thus, natural lipids appear to possess properties or include components important for the catalytic function of the CYP system, which are absent from synthetic lipid. Input of electrons, measured by NADPH consumption, exceeded product formation rate by the CPR-CYP3A4 complex in nanodiscs, indicating "leakage" in the electron flow, possibly due to uncoupling of the two enzymes. Uncoupling was shown to occur by developing a novel fluorimetric method using the dye MitSOX to detect superoxide production. The significance of this, and to what extent control of coupling could be a natural means of regulation of the CPR-CYP system, remains to be determined. Thus, phospholipid bilayer nanodiscs prove a powerful tool to enable detailed analysis of the reaction kinetics of membrane-reconstituted CPR-CYP systems, and to allow pertinent questions to be addressed concerning the integral significance of the membrane environment.
7

Études structurales par cryo-microscopie électronique d’un système d’efflux multi-drogues bactérien, impliqué dans la résistance aux antibiotiques / Cryo-electron microscopy structural studies of a bacterial multi-drug efflux pump involved in antibiotic resistance

Glavier, Marie 26 November 2018 (has links)
L'apparition croissante de bactéries pathogènes multi-résistantes à la plupart des antibiotiques disponibles apparaît comme un problème mondial de santé publique. Malheureusement, un usage excessif à la fois en médecine humaine et animale a conduit à l’apparition de souches multi-résistantes à la plupart des antibiotiques disponibles sur le marché. Il est donc urgent de mieux comprendre les mécanismes mis en place par les bactéries pour résister aux antibiotiques afin de trouver des solutions pour combattre les souches multi-résistances.Dans ce contexte, le projet de la thèse vise à mieux comprendre les bases moléculaires de l’efflux actif de drogues chez Pseudomonas aeruginosa, qui est un des plus importants mécanismes utilisés par la bactérie pour lutter contre l’action de plusieurs antibiotiques. Les systèmes d’efflux forment des complexes protéiques situés dans la paroi de la bactérie et expulsent de manière active les antibiotiques avant même qu’ils aient pu atteindre leur cible intracellulaire, les rendant ainsi inactif.L’étude structurale se focalise sur le système RND (Resistance-Nodulation and cell Division) MexA-MexB-OprM qui est constitutivement exprimé chez la bactérie sauvage et est surexprimé chez les souches résistantes. Ce complexe tripartite est composé d'un transporteur inséré dans la membrane interne, d'une protéine canal insérée dans la membrane externe et d’une protéine adaptatrice périplasmique qui relie les deux autres protéines pour former un conduit étanche traversant le périplasme. En l’absence de la connaissance de la structure du complexe tripartite, l’objectif de la thèse a été de développer une stratégie originale pour reconstituer in vitro le complexe entier dans un environnement lipidique à partir des trois composants natifs produits séparément.L’assemblage du complexe tripartite est réalisé en mélangeant MexB et OprM en Nanodisque avec MexA mimant les deux bicouches lipidiques. La structure de ce complexe tripartite a été obtenu en combinant la cryo microscopie électronique et à l’approche dite ‘des particules isolées’. La structure tridimensionnelle du complexe calculée à une résolution inférieure à 4 Å a permis de construire un modèle atomique du complexe tripartite assemblé entre deux Nanodisques.Le complexe tripartite est composé d’un trimère d’OprM, d’un trimère de MexB et d’un hexamère de MexA entourant MexB et en interaction avec OprM. Ces données ont permis de résoudre la structure complète de MexA dans le complexe dont la partie N-terminale jusqu’alors inconnue car trop flexible et décrivent pour la première fois l’ancrage de MexA dans une membrane lipidique. Les changements conformationnels sont observés sur OprM et MexB lorsqu’ils sont engagés dans le complexe avec l’ouverture de l’extrémité périplasmique d’OprM et le basculement d’une boucle de MexB permettant d’établir un contact supplémentaire avec MexA.Pour replacer cette structure tripartite dans le cycle d’efflux de l’antibiotique, celle-ci décrit un état qui s’apparente probablement à un état au repos, sachant qu’aucun ligand spécifique n’a été ajouté au cours de l’assemblage. De plus, le complexe forme un canal ouvert à son extrémité extracellulaire, fournissant le conduit pour évacuer les drogues transportées par MexB qui utilise la force protomotrice comme source d’énergie.Ce travail ouvre la perspective à des études structurales d’autres états conformationnels du système d’efflux en condition « énergisé » pour compléter la compréhension du mécanisme du cycle d’efflux. Par ailleurs, la connaissance de cette première structure du complexe natif tripartite constitue le premier pas vers le développement de molécules capables de bloquer l’assemblage du complexe à des fins thérapeutiques. En effet, de telles molécules inhiberaient l’efflux actif et restauraient l’efficacité perdue des antibiotiques actuels. / The increasing appearance of multi-drug-resistant pathogenic bacteria to most available antibiotics is emerging as a global public health problem. Unfortunately, excessive use in both human and animal medicine has led to the emergence of multi-drug-resistant strains for most antibiotics available on the market. It is therefore urgent to better understand the underlying mechanisms by which bacteria resist to antibiotics to combat multi-resistance strains. In this context, this work aims at better understanding the molecular basis of active drug efflux in Pseudomonas aeruginosa, which is one of the most important mechanisms used by the bacterium to resist to several antibiotics. Efflux systems form protein complexes in the bacterial wall and actively expel antibiotics even before they reach their intracellular target, rendering them inactive. The structural study focuses on the MexA-MexB-OprM RND (Resistance-Nodulation and cell Division) system that is constitutively expressed in wild-type bacteria and is over-expressed in resistant strains. This tripartite complex is composed of a transporter inserted into the inner membrane, a channel protein inserted in the outer membrane and a periplasmic adapter protein that connects the other two proteins to form a sealed conduit through the periplasm. In the absence of knowledge of the structure of the tripartite complex, the aim of the thesis was to develop an original strategy to reconstitute the whole complex in vitro in a lipid environment from the three native components produced separately.The assembly of the tripartite complex is made by mixing MexA with MexB and OprM in Nanodisc mimicking the two lipid bilayers. The structure of this tripartite complex was obtained by combining cryo electron microscopy and the so-called 'isolated particles' approach. The three-dimensional structure of the complex, calculated at a resolution of less than 4 Å, was used to build an atomic model of the tripartite complex assembled between two Nanodiscs. The tripartite complex is composed of an OprM trimer, a MexB trimer and a MexA hexamer surrounding MexB and interacting with OprM. We solve the complete structure of MexA whose N-terminal part hitherto unknown because of a high flexibility and describe for the first time the anchoring of MexA in a lipid membrane. The conformational changes are observed on OprM and MexB when they are assembled in the complex with the opening of the periplasmic end of OprM and the spatial re-orientation of a MexB loop to establish additional contact with MexA.To integrate this tripartite structure into the antibiotic efflux cycle, it describes a state that is probably a resting state, knowing that no specific ligand was added during assembly. In addition, the complex forms an open channel at its extracellular end, providing the conduit to evacuate the drugs carried by MexB that uses the proton motive force as a source of energy. This work opens new perspective for structural studies of other conformational states of the efflux system in "energized" conditions to fulfill our understanding of the efflux cycle mechanism. Moreover, the knowledge of this first tripartite native complex structure constitutes the first step towards the development of molecules capable of blocking the assembly of the complex for therapeutic uses. Indeed, such molecules would inhibit active efflux and restore the lost efficiency of current antibiotics.

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