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21	Existência de diferentes estados de spin dos íons Fe2+ e Fe3+ do citocromo c resultante da interação com lipossomos modelos. / Existence of different heme iron Fe2+ and Fe3+ spin states cytochrome c ions results the interaction with lipid bilayers. Maria do Rosário Zucchi 04 May 2001 (has links) A associação lipídio/citocromo c é importante e deve ser estudada, pois repercute na atividade peroxidática da proteína abordada e pode contribuir para o processo apoptótico, ou morte programada da célula, e também desempenha um papel significativo na cadeia respiratória. A natureza e a especificidade da interação do citocromo c com bicamadas lipídicas têm sido bastante investigadas ultimamente, mas informações detalhadas e precisas sobre tais assuntos ainda não existem. É aceito que ocorre primeiramente uma interação eletrostática entre a proteína citocromo c e as membranas fosfolipídicas. Em seguida, há uma interação hidrofóbica. Entretanto, ainda não é bem compreendido o papel da cadeia fosfolipídica. A associação do citocromo c com membranas lipídicas induz mudanças no estado de spin do átomo de ferro. A interação entre as vesículas carregadas e o citocromo c induz mudanças estruturais na proteína, as quais são refletidas no seu centro ativo, ou grupo heme. As mudanças do campo cristalino no sítio do ferro hemínico de forte para fraco são acompanhadas por mudanças do estado de spin de baixo para alto, respectivamente. Neste trabalho, estuda-se sistematicamente a natureza da interação entre o citocromo c e a cadeia fosfolipídica. As mudanças estruturais no grupo heme foram correlacionadas com a natureza do lipídio, ou seja, com a carga da cabeça e com o tamanho e o tipo da cadeia fosfolipídica. Foram utilizados treze lipídios diferentes, naturais e sintetizados, com cabeças polares negativas e neutras e com cadeias carbônicas saturadas e insaturadas de diferentes comprimentos. Para tal investigação, utilizamos as técnicas: Ressonância Paramagnética Eletrônica (RPE) Onda Contínua (CW) e Pulsada (PW) e Dicroísmo Circular Magnético (MCD). As técnicas enunciadas avaliam as mudanças de estado de spin e a simetria do citocromo c nos seus estados férrico e ferroso. A interação lipoprotéica lipídio/citocromo c foi avaliada com lipídios diferentes, inclusive com o lipossomo PCPECL, que mimetiza a membrana interna da mitocôndria nos eucariontes. A partir dos resultados experimentais, sugerimos um modelo para esse tipo de associação. / This association lipid/cytochrome c is interesting to study in order to understand the peroxidase activity of this protein, that plays an important role in the respiratory chain and in the apoptosis process or the programmed cell death. The nature and specificity of the interaction of cytochrome c with lipid bilayers have been major goals in recent studies, but detailed information on that issue is not yet widely available. In this regard, it is generally accepted that the electrostatic interaction is an important factor in the association of cytochrome c with phospholipid membranes, followed by a hydrophobic interaction. However, the role played by the phospholipid chain is not well understood. The association of cytochrome c with negative membranes induces a change in the heme iron spin state. The interaction between the charged vesicles and cytochrome c leads to structural changes in the active central or heme group. The changing of the crystalline field of the heme iron from strong to weak is accompanied by spin states changes from low to high spin, respectively. These facts concerned us to investigate more systematically the nature of the interaction between cytochrome c and the phospholipid chains. The lipid-induced effects in the heme iron crystalline field are correlated to the nature of the charged head group and to the size and type of the phospholipid chain. Thirteen different lipids, nature and synthetic, were used, with negative and neutra1 polar head group and saturated and unsaturated acyl chains with different length. This work investigates the change of heme iron spin state and symmetry of ferric cytochrome c using Continuous Wave (CW) and pulsed (PW) Electron Paramagnetic Resonance (EPR) and Magnetic Circular Dichroism (MCD) techniques. These techniques analyze the spin state change and the symmetry of the iron cytochrome c in its ferric and ferrous states. The effect of the different lipids were analyzed, including PCPECL membrane that mimetics the inner mitocondrial membrane in eukaryotes. Citocromo c Lipossomos RPE Cytochrome c EPR Lipid bilayers
22	Deformed Soft Matter under Constraints Bertrand, Martin January 2012 (has links) In the last few decades, an increasing number of physicists specialized in soft matter, including polymers, have turned their attention to biologically relevant materials. The properties of various molecules and fibres, such as DNA, RNA, proteins, and filaments of all sorts, are studied to better understand their behaviours and functions. Self-assembled biological membranes, or lipid bilayers, are also the focus of much attention as many life processes depend on these. Small lipid bilayers vesicles dubbed liposomes are also frequently used in the pharmaceutical and cosmetic industries. In this thesis, work is presented on both the elastic properties of polymers and the response of lipid bilayer vesicles to extrusion in narrow-channels. These two areas of research may seem disconnected but they both concern deformed soft materials. The thesis contains four articles: the first presenting a fundamental study of the entropic elasticity of circular chains; the second, a simple universal description of the effect of sequence on the elasticity of linear polymers such as DNA; the third, a model of the symmetric thermophoretic stretch of a nano-confined polymer; the fourth, a model that predicts the final sizes of vesicles obtained by pressure extrusion. These articles are preceded by an extensive introduction that covers all of the essential concepts and theories necessary to understand the work that has been done. Soft matter Biophysics Simulations Polymers Vesicles biological membranes lipid bilayers
23	A Molecular Dynamics Simulation of Vesicle Deformation and Rupture in Confined Poiseuille Flow Harman, Alison January 2013 (has links) Vesicles are simple structures, but display complex, non-linear dynamics in fluid flow. I investigate the deformation of nanometer-sized vesicles, both fully-inflated and those with excess area, as they travel in tightly confined capillaries. By varying both channel size and flow strength, I simulate vesicles as they transition from steady-state to unstable shapes, and then rupture in strong flow fields. By employing a molecular dynamics model of the vesicle, fluid, and capillary system one is able to rupture the lipid bilayer of these vesicles. This is unique in that most other numerical methods for modelling vesicles are unable to show rupture. The rupture of fully-inflated vesicles is applicable to drug delivery in which the release of the encapsulated medicine needs to be controlled. The deformation and rupture of vesicles with excess area could be applicable to red blood cells which have similar rheological properties. vesicles lipid bilayers biophysics simulations poiseuille flow liposomes biological membranes
24	Geometry-Dependent Nonequilibrium Steady-State Diffusion and Adsorption of Lipid Vesicles in Micropillar Arrays Liu, Fangjie, Abel, Steven M., Collins, Liam, Srijanto, Bernadeta R., Standaert, Robert, Katsaras, John, Collier, Charles Patrick 09 May 2019 (has links) Micro- and nanofabricated sample environments are useful tools for characterizing diffusion in confined aqueous environments. The steady-state diffusion and adsorption of unilamellar lipid vesicles in arrays of hydrophilic micropillars is investigated. Gradients in the coverage of fluorescently labeled, pillar-supported lipid films, formed from vesicle fusion, are determined from 3D z-stack images using confocal microscopy. The gradients are the result of preferential adsorption of vesicles near the tops of the pillars, which progressively deplete them from solution as they diffuse toward the base of the array. However, the increased propensity for vesicle adsorption near the pillar tops compared to the confined spaces between pillars results in the formation of confluent supported lipid bilayers at the pillar tops that resist the adsorption of additional vesicles while leaving the pillar surfaces below available for binding. This results in a reduction in the numbers of depleted vesicles compared to what one would anticipate based on diffusive fluxes. The resulting inhomogeneous spatial profiles of lipid structures on the pillars are the result of the system being maintained in a dissipative, nonequilibrium steady state during incubation of the pillar arrays in the vesicle solution, which is ultimately quenched by rinsing away the unbound, freely diffusing vesicles. adsorption diffusion microfabrication supported lipid bilayers vesicles Chemistry
25	FORMATION, DYNAMICS AND CHARACTERIZATION OF SUPPORTED LIPID BILAYERS ON SiO2 NANOPARTICLES Ahmed, Selver January 2012 (has links) This work is devoted to understanding the formation of supported lipid bilayers (SLBs) on curved surfaces as a function of lipid properties such as headgroup charge/charge density and alkyl chain length, and nanoparticle properties such as size and surface characteristics. In particular, the formation of SLBs on curved surfaces was studied by varying the size of the underlying substrate SiO2 nanoparticles with size range from 5-100 nm. Curvature-dependent shift in the phase transition behavior of these supported lipid bilayers was observed for the first time. We found that the phase transition temperature, Tm of the SLBs first decreased with decreasing the size of the underlying support, reached a minimum, and then increased when the size of the particles became comparable with the dimensions of the lipid bilayer thickness; the Tm was above that of the multilamellar vesicles (MLVs) of the same lipids. The increase in Tm indicated a stiffening of the supported bilayer, which was confirmed by Raman spectroscopic data. Moreover, Raman data showed better lipid packing and increased lateral order and trans conformation for the SLBs with increasing the curvature of the underlying support and decrease of the gauche kinks for the terminal methyl groups at the center of the bilayer. These results were consistent with a model in which the high free volume and increased outer headgroup spacing of lipids on highly curved surfaces induced interdigitation in the supported lipids. These results also support the symmetric lipid exchange studies of the SLBs as a function of the curvature, which was found to be slower on surfaces with higher curvature. Further, the effect of surface properties on the formation of SLBs was studied by changing the silanol density on the surface of SiO2 via thermal/chemical treatment and monitoring fusion of zwitterionic lipids onto silica (SiO2) nanoparticles. Our findings showed that the formation of SLBs was faster on the surfaces with lower silanol density and concomitantly less bound water compared to surfaces with higher silanol density and more bound water. Since the two SiO2 nanoparticles were similar in other respects, in particular their size and charge (ionization), as determined by zeta potential measurements, differences in electrostatic interactions between the neutral DMPC and SiO2 could not account for the difference. Therefore the slower rate of SLB formation of DMPC onto SiO2 nanoparticles with higher silanol densities and more bound water was attributed to greater hydration repulsion of the more hydrated nanoparticles. Lastly, we have investigated the effect and modulation of the surface charge of vesicles on the formation of SLBs by using different ratios of zwitterionic and cationic DMPC/DMTAP lipids. Through these studies we discovered a procedure by which assemblies of supported lipid bilayer nanoparticles, composed of DMPC/DMTAP (50/50) lipids on SiO2, can be collected and released from bilayer sacks as a function of the phase transition of these lipids. The lipids in these sacks and SLBs could be exchanged by lipids with lower Tm via lipid transfer. / Chemistry Chemistry, Physical Nanoscience Nanotechnology Effect of Curvature On Lipid Bilayers Nanoparticle Supported Lipid Bilayers
26	Computer Simulations of Membrane–Sugar Interactions Kapla, Jon January 2016 (has links) Carbohydrate molecules are essential parts of living cells. They are used as energy storage and signal substances, and they can be found incorporated in the cell membranes as attachments to glycoproteins and glycolipids, but also as free molecules. In this thesis the effect of carbohydrate molecules on phospholipid model membranes have been investigated by the means of Molecular Dynamics (MD) computer simulations. The most abundant glycolipid in nature is the non-bilayer forming monogalactosyldiacylglycerol (MGDG). It is known to be important for the membrane stacking typical for the thylakoid membranes in plants, and has also been found essential for processes related to photosynthesis. In Paper I, MD simulations were used to characterize structural and dynamical changes in a lipid bilayer when MGDG is present. The simulations were validated by direct comparisons between dipolar couplings calculated from the MD trajectories, and those determined from NMR experiments on similar systems. We could show that most structural changes of the bilayer were a consequence of lipid packing and the molecular shape of MGDG. In certain plants and organisms, the enrichment of small sugars such as sucrose and trehalose close to the membrane interfaces, are known to be one of the strategies to survive freezing and dehydration. The cryoprotecting abilities of these sugar molecules are long known, but the mechanisms at the molecular level are still debated. In Papers II–IV, the interactions of trehalose with a lipid bilayer were investigated. Calculations of structural and dynamical properties, together with free energy calculations, were used to characterize the effect of trehalose on bilayer properties. We could show that the binding of trehalose to the lipid bilayer follows a simple two state binding model, in agreement with recent experimental investigations, and confirm some of the proposed hypotheses for membrane–sugar interactions. The simulations were validated by dipolar couplings from our NMR investigations of TRH in a dilute liquid crystal (bicelles). Furthermore, the assumption about molecular structure being equal in the ordered and isotropic phases was tested and verified. This assumption is central for the interpretation of experimentally determined dipolar couplings in weakly ordered systems. In addition, a coarse grain model was used to tackle some of the problems with slow dynamics that were encountered for trehalose in interaction with the bilayer. It was found that further developments of the interaction models are needed to properly describe the membrane–sugar interactions. Lastly, from investigations of trehalose curvature sensing, we concluded that it preferably interacts in bilayer regions with high negative curvature. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p> Molecular simulations Molecular dynamics Lipid bilayers Carbohydrates Biological membranes Trehalose Glycolipids Membrane—sugar interactions
27	Uso da microscopia eletroquímica de varredura (SECM) no estudo de sistemas micelares e do transporte de espécies químicas através de membranas lipídicas / The use of scanning electrochemical microscopy (SECM) on studies of micellar systems and in the transport of chemical species through lipid membranes Lima, Alex da Silva 31 July 2015 (has links) A presente tese versa sobre resultados obtidos na aplicação da microscopia eletroquímica de varredura no estudo de sistemas micelares e no estudo de bicamadas lipídicas. Os estudos envolvendo sistemas micelares foram realizados utilizando a SECM no modo substrato-gerador/microeletrodo-coletor. Neste modo de operação, um microeletrodo de platina foi posicionado próximo a um substrato de platina e utilizado para monitorar espécies eletrogeradas nesse substrato. Conhecendo o tempo necessário para a espécie eletrogerada difundir do substrato até o microeletrodo, foi possível aplicar a equação de Einstein-Smoluchowski para determinar o coeficiente de difusão da espécie eletroativa e de micelas de surfactantes. Como as micelas não são eletroativas, o ferroceno eletrogerado no substrato e incorporado nas micelas foi utilizado como sonda para a estimativa do tempo de difusão. Os resultados obtidos para o surfactante brometo de tetradecil trimetil amônio (C14TABr) corroboram dados reportados na literatura, demonstrando a utilidade da metodologia proposta no estudo de sistema micelares. Também foram realizados experimentos envolvendo micelas do surfactante cloreto de 1-alquil-3-metilimidazólio, CxMelmCl (x = 10, 12, 14, 16) e com os resultados obtidos foi possível evidenciar o efeito da cadeia carbônica no coeficiente de difusão das espécies. Os experimentos envolvendo a permeação de substâncias através de bicamadas lipídicas foram realizados em duas etapas. Os primeiros ensaios foram realizados utilizando modelo de membrana semipermeável (papel celofane) com o intuito de verificar a aplicabilidade da SECM no monitoramento de espécies eletroativas que permeiam através da membrana. Na segunda etapa, apresentou-se metodologia para a obtenção de microfuros em folhas de poliestireno utilizados para a formação das bicamadas lipídicas, assim como detalhes sobre a construção da célula de medidas utilizadas nos experimentos de permeação. Foram realizados experimentos envolvendo o uso de bicamadas lipídicas planas obtidas pelo método de Miller preparadas com lecitina de soja. Esses experimentos foram realizados com o intuito de avaliar a estabilidade e para verificar a permeabilidade de algumas substâncias nas bicamadas formadas. Os experimentos de permeação foram realizados posicionando um microeletrodo próximo à membrana, com posterior detecção amperométrica da espécie eletroativa que atravessa a membrana. / This thesis shows results on the use of scanning electrochemical microscopy in the study of micellar systems and lipid bilayers. Studies involving micellar systems were performed by using SECM in the substrate-generator/tip-collector mode. In this operation mode a platinum microelectrode was positioned close to a platinum substrate and used to monitor electrogenerated species on this surface. Taking into account the time for the electrogenerated species to diffuse from the substrate to the microelectrode, the diffusion coefficient of the electroactive species and of the micelles can be calculated by applying the Einstein-Smoluchowski equation. As micelles are not electroactive, ferrocene electrogenerated on the substrate and incorporated into the micelles was used as a probe to estimate the diffusion time. The results obtained for tetradecyl trimethyl ammonium bromide (C14TABr) corroborate those reported in the literature, demonstrating the applicability of the proposed methodology in the study of micellar systems. Experiments with micelles obtained from 1-alkyl-3-methylimidazolium, CxMelmCl (x = 10, 12, 14, 16) chloride surfactants were also performed and results showed the effect of the carbon chain in the diffusion coefficient. Experiments involving the permeation of chemical species through lipid bilayers were carried out in two steps. A membrane model (cellophane) was preliminary used in order to investigate the possibility of using SECM as a tool for monitoring the permeation of electroactive species through the membrane. Then, a methodology for obtaining microholes in polystyrene sheets used to form lipid bilayers was presented, as well as details about the design of an electrochemical cell used in the permeation experiments. Experiments involving the use of planar lipid bilayers obtained by the method of Miller prepared using soybean lecithin were performed. These experiments were carried out in order to evaluate the stability and to check the permeation of some substances through the prepared bilayers. Permeation experiments were performed by placing the microelectrode close to the membrane with subsequent amperometric detection of any electroactive species that cross the membrane Bicamadas lipídicas Lipid bilayers Micelas Micelles Microelectrode Microeletrodo Microscopia eletroquímica de varredura Scanning electrochemical microscopy
28	Investigation of Snare-Mediated Membrane Fusion Mechanism Using Atomic Force Microscope Spectroscopy Abdulreda, Midhat H. 11 December 2007 (has links) Membrane fusion is essential for survival in eukaryotic cells. Many physiological processes such as endocytosis and exocytosis are mediated by membrane fusion, which is driven by highly specialized and conserved family of proteins. Neuronal soluble Nethylmaleimide- sensitive factor attachment protein receptors (SNAREs) mediate vesicle fusion with the plasma membrane during neurotransmitter release; however, the mechanism for SNARE-mediated membrane fusion remains to be established. In the current work, we aimed at investigating this mechanism using atomic force microscope (AFM) spectroscopy. We established an AFM lipid bilayer system, which proved effective in detecting fusion of bilayers and measuring compression forces required to generate fusion. It also revealed that SNARE-mediated membrane fusion proceeds through an intermediate hemifused state. Using this system, we revealed the energy landscape for membrane fusion using a dynamic force approach. We carried out compression force measurements at different compression rates and a significant reduction in the force was observed when SNAREs were present in the bilayers. The results also indicated that a single energy barrier governed membrane fusion in our experimental system. The energy barrier is characterized by its width and height, which determine the slope of the activation potential. With SNAREs in the opposing (trans) bilayers, the width of the barrier increased > 2 fold, which is interpreted as an increase in the compressibility of the membranes and subsequently a greater ease in their deformation and fusion under compression. Moreover, specific perturbations to the SNARE interaction interfered with the observed facilitation of membrane fusion, which indicated the involvement of SNAREs in the observed fusion facilitation and increase in the fusion rate. Furthermore, dissociation kinetics analysis of the SNARE interaction revealed a strong binding force during trans SNARE-complex formation, and a correlation between the strength of the SNARE interaction and the degree of fusion facilitation was established. In conclusion, the present findings provide support for a mechanism for SNAREmediated membrane fusion, where trans-interaction between SNAREs provides close apposition of the membranes and reduces fusion energy requirements by locally destabilizing the bilayers, in which the SNAREs are anchored, through pulling on or tilting of their transmembrane segments.
29	Formation and Characterization of Polymerized Supported Phospholipid Bilayers and the in vitro Interactions of Macrophages and Fibroblasts. Page, Jonathan Michael 01 August 2010 (has links) Planar supported, polymerized phospholipid bilayers (PPBs) composed of 1,2-bis[10-(2’,4’-hexadienoyloxy)decanoyl]-sn-glycero-3-phosphocholine (bis-SorbPC or BSPC) were generated by a redox polymerization method. The PPBs were supported by a silicon substrate. The PPBs were characterized and tested for uniformity and stability under physiological conditions. The PPBs were analyzed in vitro with murine derived cells that are pertinent to the host response. Cellular attachment and phenotypic changes in RAW 264.7 macrophages and NIH 3T3 fibroblasts were investigated on PPBs and compared to bare silicon controls. Fluorescent and SEM images were used to observe cellular attachment and changes in cellular behavior. The PPBs showed much lower cellular adhesion for both cell lines than bare silicon controls. Of the cells that attached to the PPBs, a very low percentage showed the same morphological expressions as seen on the controls. The hypothesis generated from this work is that defects in the PPBs mediated the cellular attachment and morphological changes that were observed. Finally, a layer-by-layer (LbL) deposition of a poly(acrylic acid) (PAA) and poly(N-vinylpyrrolidone) (PNVP) alternating bilayer was attempted as a proof of concept for future modification of this system. Polymerized lipid bilayers bis-SorbPC host response macrophage fibroblast. Polymer and Organic Materials
30	Molecular Dynamics Simulations of Fluid Lipid Membranes Brandt, Erik G. January 2011 (has links) Lipid molecules form thin biological membranes that envelop all living cells, and behave as two-dimensional liquid sheets immersed in bulk water. The interactions of such biomembranes with their environment lay the foundation of a plethora of biological processes rooted in the mesoscopic domain - length scales of 1-1000 nm and time scales of 1-1000 ns. Research in this intermediate regime has for a long time been out of reach for conventional experiments, but breakthroughs in computer simulation methods and scattering experimental techniques have made it possible to directly probe static and dynamic properties of biomembranes on these scales. Biomembranes are soft, with a relatively low energy cost of bending, and are thereby influenced by random, thermal fluctuations of individual molecules. Molecular dynamics simulations show how in-plane (density fluctuations) and out-of-plane (undulations) motions are intertwined in the bilayer in the mesoscopic domain. By novel methods, the fluctuation spectra of lipid bilayers can be calculated withdirect Fourier analysis. The interpretation of the fluctuation spectra reveals a picture where density fluctuations and undulations are most pronounced on different length scales, but coalesce in the mesoscopic regime. This analysis has significant consequences for comparison of simulation data to experiments. These new methods merge the molecular fluctuations on small wavelengths, with continuum fluctuations of the elastic membrane sheet on large wavelengths, allowing electron density profiles (EDP) and area per lipid to be extracted from simulations with high accuracy. Molecular dynamics simulations also provide insight on the small-wavelength dynamics of lipid membranes. Rapidly decaying density fluctuations can be described as propagating sound waves in the framework of linearized hydrodynamics, but there is a slow, dispersive, contribution that needs to be described by a stretched exponential over a broad range of length- and time scales - recent experiments suggest that this behavior can prevail even on micrometer length scales. The origin of this behavior is discussed in the context of fluctuations of the bilayer interface and the molecular structure of the bilayer itself. Connections to recent neutron scattering experiments are highlighted. / QC 20111014 / Modelling of biological membranes biological fluid dynamics biomembranes hydrodynamics lipid bilayers molecular dynamics neutron spin echo

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