Spelling suggestions: "subject:"lipidmembranen"" "subject:"lipidmembrane""
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Konformace adenylátcyklázového toxinu Bordetella pertussis. / Conformation of the adenylate cyclase toxin of Bordetella pertussis.Motlová, Lucia January 2021 (has links)
This work is focused on the RTX (Repeats in ToXin) domains structure of selected RTX toxins and its impact on secretion and protein folding. The structural analysis included RTX domains of ApxI (Actinobacillus pleuropneumoniae-RTX-toxin I) from Actinobacillus pleuropneumoniae, HlyA (Alfa-hemolysin) from Escherichia coli and LtxA (Leukotoxin A) from Aggregatibacter actinomycetemcomitans and blocs 4 a 5 RTX domain CyaA (adenylate cyclase toxin) from Bordetella pertussis. The structures of LtxA RTX domain and CyaA RTX blocs 4 and 5 were obtained and characterized. Two models of CyaA RTX domain were built based on SAXS (Small Angle X-ray Scattering) model, previously solved RTX structures and RTX structures presented here.
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Mesoscopic structural dynamics and mechanics of cell membrane models / 細胞膜モデルのメゾスコピックな構造ダイナミクスとメカニクスYamamoto, Akihisa 23 March 2015 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(理学) / 乙第12911号 / 論理博第1547号 / 新制||理||1590(附属図書館) / 32121 / 京都大学大学院理学研究科・物理学・宇宙物理学専攻 / (主査)講師 市川 正敏, 教授 山本 潤, 教授 田中 耕一郎 / 学位規則第4条第2項該当 / Doctor of Science / Kyoto University / DGAM
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Design of Biomembrane-Mimicking Substrates of Tunable Viscosity to Regulate Cellular MechanoresponseMinner, Daniel Eugene 20 March 2012 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Tissue cells display mechanosensitivity in their ability to discern and respond to changes in the viscoelastic properties of their surroundings. By anchoring and pulling, cells are capable of translating mechanical stimuli into a biological response through a process known as mechanotransduction, a pathway believed to critically impact cell adhesion, morphology and multiple cellular processes from migration to differentiation. While previous studies on polymeric gels have revealed the influence of substrate elasticity on cellular shape and function, a lack of suitable substrates (i.e. with mobile cell-substrate linkers) has hindered research on the role of substrate viscosity. This work presents the successful design and characterization of lipid-bilayer based cell substrates of tunable viscosity affecting cell-substrate linker mobility through changes in viscous drag. Here, two complementary membrane systems were employed to span a wide range of viscosity. Single polymer-tethered lipid bilayers were used to generate subtle changes in substrate viscosity while multiple, polymer-interconnected lipid bilayer stacks were capable of producing dramatic changes in substrate viscosity. The homogeneity and integrity of these novel multibilayer systems in the presence of adherent cells was confirmed using optical microscopy techniques. Profound changes in cellular growth, phenotype and cytoskeletal organization confirm the ability of cells to sense changes in viscosity. Moreover, increased migration speeds coupled with rapid area fluctuations suggest a transition to a different migration mode in response to the dramatic changes in substrate viscosity.
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Ezrin activation in vitro: Investigation of ezrin's conformation and the interaction between ezrin and F-actinBraunger, Julia 21 June 2013 (has links)
No description available.
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The influence of membrane bound proteins on phase separation and coarsening in cell membranesWitkowski, Thomas, Backofen, Rainer, Voigt, Axel 07 April 2014 (has links) (PDF)
A theoretical explanation of the existence of lipid rafts in cell membranes remains a topic of lively debate. Large, micrometer sized rafts are readily observed in artificial membranes and can be explained using thermodynamic models for phase separation and coarsening. In live cells such domains are not observed and various models are proposed to describe why the systems do not coarsen. We review these attempts critically and show within a phase field approach that membrane bound proteins have the potential to explain the different behaviour observed in vitro and in vivo. Large scale simulations are performed to compute scaling laws and size distribution functions under the influence of membrane bound proteins and to observe a significant slow down of the domain coarsening at longer times and a breakdown of the self-similarity of the size-distribution function. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Podporované fosfolipidové dvojvrstvy a jejich interakce s proteiny studovaná pomocí elipsometrie, mikroskopie atomových sil a konfokální fluorescenční mikroskopie / Supported Phospholipid Bilayers and their Interactions with Proteins Studied by Ellipsometry, Atomic Force Microscopy and Confocal Fluorescence MicroscopyMacháň, Radek January 2012 (has links)
Supported lipid bilayers have been used as an artificial model of biological membranes and their interaction with 5 selected antimicrobial peptides was studied by several experimental techniques, mainly ellipsometry, laser scanning microscopy and fluorescence correlation spectroscopy. The thesis explains basic principles of the applied techniques focusing on their aspects relevant to characterization of lipid bilayers. The biological significance of antimicrobial peptides, their modes of interaction with membranes and the basic characteristics of the selected peptides are briefly discussed. The following text describes the main types of experimental studies performed and the interpretation of their results. Peptide-induced changes in lipid bilayer morphology were characterized by ellipsometry and laser scanning microscopy. Most interesting effects were observed in the case of melittin, which induced formation of long lipid tubules protruding from the bilayer. Lipid lateral diffusion measured by fluorescence correlation spectroscopy can provide information on bilayer organization on length-scales below resolution of optical microscopy.
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Properties of Conductance and Inhibition of Proton Channels: M2 from Influenza A Virus and Fo from Escherichia coli ATP SynthaseMoffat, Jeffrey C. 30 June 2006 (has links) (PDF)
Proton channels are essential for many of the processes of life. The influenza A viral protein M2 is responsible for sensing the conditions necessary for viral RNA release. The proton-translocating FoF1 ATPase (ATP synthase) uses a proton gradient to drive adenosine triphosphate (ATP) synthesis. We have directly measured proton uptake in vesicles containing reconstituted M2 or FO by monitoring external pH after addition of valinomycin to vesicles with 100-fold diluted external [K+]. This proton flux assay was utilized to quantify proton flux through single M2 and Fo channels. Contrary to previous reports, proton uptake by M2 was not significantly altered by acidification of the extravesicular pH. We conclude that pH only weakly affects proton flux through M2 in the pH range of 5.4 - 7.0. Theoretical analysis utilized for such vesicle uptake assays illuminates the appropriate time scale of the initial slope and an important limitation that must be placed on inferences about channel ion selectivity. The rise in pH over 10 seconds after ionophore addition yielded time-averaged single channel conductances of 0.35±0.2 aS and 0.72±0.4 aS at pH 5.4 and 7.0 respectively. Such a low time-average conductance implies that M2 is only conductive 10^-6 to 10^-4 of the time. M2 selectivity for hydrogen over potassium is ~10^7. Fo translocates protons across membranes, converting electrochemical energy to rotational inertia. Previous experiments have been partially confounded by a contaminating channel, CL, which co-purifies with Fo and leaks cations. CL activity is shown to not decrease following deletion of the previously uncharacterized yraM open reading frame of E. coli. Fo purified from a deletion strain lacking yraM is just as active as Fo purified from the wild-type strain. Using Fo from the deletion strain, the single-hit hypothesis of DCCD inhibition of passive proton flux through Fo was examined. A DCCD-induced reduction in ATP synthase activity correlates with a reduction in the total initial slope, the number of functional Fo per µg protein, and the single channel proton flux. At least 2 DCCD per Fo are required to totally inactivate passive proton flux. M2 and Fo have similar single channel conductances but different open probabilities.
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Theoretical Modeling of Polymeric and Biological Nanostructured MaterialsRahmaninejad, Hadi 23 February 2023 (has links)
Polymer coatings on periodic nanostructures have facilitated advanced applications in various fields. The performance of these structures is intimately linked to their nanoscale characteristics. Smart polymer coatings responsive to environmental stimuli such as temperature, pH level, and ionic strength have found important uses in these applications. Therefore, to optimize their performance and improve their design, precise characterization techniques are essential for understanding the nanoscale properties of polymer coating, especially in response to stimuli and interactions with the surrounding medium. Due to their layered compositions, applying non-destructive measurement methods by X-ray/neutron scattering is optimal. These approaches offer unique insights into the structure, dynamics, and kinetics of polymeric coatings and interfaces.
The caveat is that scattering methods require non-trivial data modeling, particularly in the case of periodic structures, which result in strong correlations between scattered beams. The dynamical theory (DT) model offers an exact model for interpreting off-specular signals from periodically structured surfaces and has been validated on substrates measured by neutron scattering. In this dissertation, we improved the model using a computational optimization approach that simultaneously fits specular and off-specular scattering signals and efficiently retrieves the three-dimensional sample profile with high precision. In addition, we extended this to the case of X-ray scattering. We applied this approach to characterize polymer brushes for nanofluidic applications and protein binding to modulated lipid membranes. This approach opens new possibilities in developing soft matter nanostructured substrates with desired properties for various applications. / Doctor of Philosophy / Polymer coatings on nanopatterned surfaces have recently facilitated advanced applications in various fields, particularly biotechnology. For example, multichannel surfaces coated with polymer can serve as nanofluidic devices for precise control of fluid flow in drug screening and detection of specific biomolecules. Moreover, polymer-coated nanopatterned surfaces, which possess similar properties to the extracellular matrix, provide excellent substrates for biological studies. The performance of these systems is closely tied to their nanoscale features, such as the thickness and conformation of the polymer layers. Therefore, high-resolution non-invasive nanoscale characterization techniques are essential for investigating these coatings to optimize their performance and enhance their design. X-ray/neutron scattering offers a non-destructive measurement method with unique capabilities in the nanoscale characterization of polymer coatings. However, scattering methods require non-trivial data modeling, particularly in the case of layered coatings on patterned surfaces.
To tackle this challenge, we improved a dynamical theory (DT) model that allows for precise modeling of neutron and X-ray scattering signals from such systems. Using a computational optimization approach, the model enables efficient retrieval of the three-dimensional sample profile with high accuracy. We applied this approach to characterize polymer brushes for nanofluidic applications and protein binding to modulated lipid membranes. This methodology opens up new avenues for developing customizable, nanostructured substrates made from soft materials that possess tailored properties for a wide range of uses.
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Vliv vápenatých iontů a cholesterolu na kanálotvornou aktivitu Adenylát-cyklázového toxinu / Effect of calcium ions and cholesterol on channel forming activity of Adenylate-cyclase toxinDoktorová, Eliška January 2013 (has links)
1 Abstract Adenylate cyclase toxin (CyaA) is one of the major virulence factors of bacterium Bordetella pertussis, which is a causative agent of whooping cough. CyaA belongs to the family of RTX toxin-hemolysins. The toxin targets primarily cells expressing integrin receptor CD11b/CD18 but it can also penetrate cells lacking this receptor. CyaA acts on host cells by two independent activities. One is formation of small cation-selective channels, which can lead to colloid osmotic lysis of target cells. The second is disruption of cell signaling through the translocation of the adenylate cyclase (AC) domain to host cell cytosol, which leads to the conversion of ATP into cyclic AMP. It was recently shown that cholesterol affects endocytosis of CyaA. CyaA translocates it's AC domain after relocation of CyaA molecule to the cholesterol-rich lipid raft (Bumba et al. 2010). In this work I examined the effect of cholesterol on channel- forming activity and selectivity of ion channels created by CyaA. For measurements I used artificial membranes enriched with cholesterol. CyaA channels are voltage-dependent. The positive membrane potential on the side of toxin is rquired for incorporation of CyaA molecule into cell membrane. I tried to find out whether the value of voltage has effect on channels opening time....
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Topologie a funkce transmembránové domény kolicinu U, bakterie Shigella boydii / Topology and function of the transmembrane domain of colicin U produced by Shigella boydiiDolejšová, Tereza January 2015 (has links)
Colicin U is a protein produced by strains of bacterium Shigella boydii. It exhibits antibacterial activity against some bacterial strains Shigella and Escherichia. Based on sequence homology with colicins A, B and N, the colicin U is classified as a pore-forming colicin. Interaction of colicin U with attacked bacteria is ensured by three-step mechanism: 1) First colicin U interacts with surface receptors OmpA, OmpF and core of LPS. 2) Thereafter the colicin is translocated to periplasm through interaction with Tol proteins. 3) Finally colicin U interacts with the inner membrane of the attacked bacteria causing its depolarization. In this thesis I demonstrated pore-forming features of colicin U and further observed characteristics and properties of these pores. Using methods of measuring on black lipid membranes I determined a single channel conductance (19 pS), ion selectivity, the influence of various conditions on the behaviour of the pores. These findings, in many cases, correspond to the findings on other related colicins. Furthermore, I successfully determined the pore diameter of colicin U ( ≈ 0,8 nm). The next section of the thesis focuses on creation of single cysteine mutations of colicin U. Subsequently I produced five mutant variants of colicin U and verified their functionality so that...
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