Global ETD Search

11	Single Proteins under the Microscope: Conformations, Dynamics and Medicinal Therapies Liu, Baoxu 20 June 2014 (has links) We applied single-molecule fluorescence (SMF) methods to probe the properties of individual fluorescent probes, and to characterize the proteins of interest to which these probes were attached. One remarkable advantage of SMF spectroscopy is the ability to investigate heterogeneous subpopulations of the ensemble, which are buried in ensemble averaging in other measurements. Other advantages include the ability to probe the entire dynamic sequences of a single molecule transitioning between different conformational states. For the purpose of having an extended observation of single molecules, while maintaining the native nanoscale surroundings, we developed an improved vesicle preparation method for encapsulating scarce biological samples. SMF investigations revealed that molecules trapped in vesicles exhibit nearly ideal single-emitter behavior, which therefore recommends the vesicle encapsulation for reproducible and reliable SMF studies. Hyperactive Signal-Transducer-and-Activator-of-Transcription 3 (STAT3) protein contributes significantly to human cancers, such as leukemia and lymphoma. We have proposed a novel therapeutic strategy by designing a cholesterol-based protein membrane anchor (PMA), to tether STAT3 to the cell membrane and thus inhibit unwanted transcription at the cell nucleus. We designed in vitro proof-of-concept experiments by encapsulating STAT3 and PMAs in phospholipid vesicles. The efficiency and the stability of STAT3 anchoring in the lipid membrane were interrogated via quantitative fluorescence imaging and multiparameter SMF spectroscopy. Our in vitro data paved the way for the in vivo demonstration of STAT3 inhibition in live cells, thus demonstrating that PMA-induced protein localization is a conceptually viable therapeutic strategy. The recent discovery of intrinsically disordered proteins (IDPs) highlights important exceptions to the traditional structure-function paradigm. SMF methods are very suited for probing the properties of such highly heterogeneous systems. We studied in detail the effects of electrostatics on the conformational disorder of an IDP protein, Sic1 from yeast, and found that the electrostatic repulsion is a major factor controlling the dimensions of Sic1. Based on our data we also conclude that a rod-like shape seems a better candidate than a random Gaussian chain to describe and predict the behavior of Sic1. Intrinsically Disordered Protein New Cancer Therapies Protein Membrane Anchorage 0752 0786 0760
12	Single-molecule fluorescence detection in molecular biology / Single-molecule fluorescence detection in molecular biology FESSL, Tomáš January 2012 (has links) SMFD techniques offer genuine detection possibilities which are often inaccessible using ensemble methods. This was demonstrated in three projects investigating translocation activity of CHD4 protein, analysis of MS2 phage capsid assembly and in-cell characterization of DNA structure. In other projects, binding interactions between two fluorescent probes and a short oligonucleotide were characterized and all optical depth of focus extended microscope configuration for imaging of individual molecules inside bacterial cells was developed and tested.
13	Probing Molecular Stoichiometry by Photon Antibunching and Nanofluidics Assisted Imaging in Solution Cheng, Hao 18 May 2017 (has links) No description available. 571.4 single-molecule fluorescence nanofluidics brightness analysis molecular stoichiometry antibunching stroboscopic imaging Biologie (PPN619462639)
14	Molecular Size and Charge Effects on Nucleocytoplasmic Transport Studied By Single-Molecule Microscopy Goryaynov, Alexander G. 03 April 2013 (has links) No description available. Biophysics 3D imaging nucleoporins nuclear pore complex single-molecule fluorescence super-resolution microscopy
15	Auto-inhibition mechanism of the guanine nucleotide exchange factor Tiam1 Xu, Zhen 01 August 2016 (has links) The Rho family of guanosine triphosphatases (GTPases) function as binary molecular switches, which play an important role in the regulation of actin cytoskeleton rearrangement and are involved in several critical cellular processes including cell adhesion, division and migration. Rho GTPases are specifically activated by their associated guanine nucleotide exchange factors (RhoGEFs). Dysregulation of RhoGEFs function through mutation or overexpression has been implicated in oncogenic transformation of cells and linked to several kinds of invasive and metastatic forms of cancer. T-cell lymphoma invasion and metastasis 1 (Tiam1) is a multi-domain Dbl family GEF protein and specifically activates Rho GTPase Rac1 through the catalytic Dbl homology and Pleckstrin homology (DH-PH) bi-domain. Previous works have shown that the nucleotide exchange function of the full-length Tiam1 is auto-inhibited and can be activated by N-terminal truncation, phosphorylation and protein-protein interactions. However, the molecular mechanisms of Tiam1 GEF auto-inhibition and activation have not yet been determined. In this study, the N-terminal PH-CC-Ex domain of Tiam1 is shown to directly inhibit the GEF function of the catalytic DH-PH domain in vitro. Using fluorescencebased kinetics experiments, we demonstrate that the auto-inhibition of Tiam1 GEF function occurs by a competitive inhibition model. In this model, the maximum velocity of catalytic activity remains unchanged, but the Michaelis-Menten constant of the auto-inhibited Tiam1 (the PH-PH fragment) on the substrate Rac1 is increased compared to the activated Tiam1 (the catalytic DH-PH domain alone). Through small angle X-ray scattering (SAXS), the structure of auto-inhibited Tiam1 (the PH-PH fragment) is shown to form a closed conformation in which the catalytic DH-PH domain is blocked by the N-terminal PH-CC-Ex domain. Taken together, these findings demonstrate the molecular mechanism of Tiam1 GEF autoinhibition in which the PH-CC-Ex domain of Tiam1 inhibits its GEF function by preventing the substrate Rho GTPase Rac1 from accessing the catalytic DH-PH bi-domain. Auto-inhibition Enzymatic kinetics Guanine nucleotide exchange factor single molecule fluorescence TIRF Small angle X-ray scattering Tiam1 Biochemistry
16	Molekulare Orientierung als Kontrastmechanismus in der Fluoreszenzmikroskopie und konfokale Multidetektor-Scanning-Mikroskopie / Molecular Orientation as Contrast Mechanism for Fluorescence Microcopy and Confocal Multidetector-Scanning-Microscopy Grunwald, Matthias 24 September 2015 (has links) Die vorliegende Arbeit befasst sich mit zwei neuen methodischen Ansätzen auf dem Gebiet der Fluoreszenzmikroskopie. Im ersten Teil der Arbeit wir eine Methode vorgestellt, mit der die Winkelselektivität der Fluoreszenzanregung verbessert werden kann. Die ExPAN (excitation polarization angle narrowing) genannte Technik nutzt stimulierte Emission, um den Effekt der Photoselektion zu vergrößern. ExPAN lässt sich potentiell für verschiedene Methoden einsetzen, in denen fluoreszenzmarkierte Proben untersucht werden und ist insbesondere im Kontext von Fluoreszenzanisotropie-Messungen oder der Bestimmung von molekularen Orientierungen von Interesse. Solche Methoden finden in den Biowissenschaften breite Anwendung und werden z.B. zum Studium von Rezeptor-Liganden-Interaktionen oder der Proteindynamik eingesetzt. Im Rahmen der Arbeit wird ExPAN in Kombination mit einem neuen Ansatz in der Weitfeldmikroskopie untersucht, bei der die Orientierung von Farbstoffmolekülen als Kontrastmechanismus genutzt wird. Dabei wird die Polarisationsrichtung des Anregungslichts rotiert, um Informationen über die molekulare Orientierung zu gewinnen. Aufgrund der Photoselektion weist das Fluoreszenzsignal von Molekülen mit bevorzugter Ausrichtung dadurch eine periodische Modulation auf. Es wird gezeigt, dass diese Information zur Unterscheidung von Molekülen mit abweichender Orientierung genutzt werden kann, selbst wenn sich deren Signale räumlich überlagern. Für die Versuche wurde ein modifiziertes Weitfeld-Mikroskop konstruiert und die Methode zum einen experimentell an Einzelmolekülen und zum anderen mittels Simulationen erprobt. Dabei konnten Signale von Farbstoffmolekülen mit einem Abstand von bis zu 80 nm separiert werden. Darüber hinaus wurde ein moduliertes Fluoreszenzsignal bei oberflächenmarkierten Mikropartikeln in wässriger Lösung sowie bei fixierten biologischen Proben beobachtet. Eine Verbesserung der Photoselektion durch ExPAN wird experimentell nachgewiesen und gezeigt, dass mit ExPAN auch ähnlich orientierte Moleküle unterschieden werden können. Im zweiten Teil der Arbeit wird eine Methode zur Verbesserung der Auflösung von konfokalen Laser-Scanning-Mikroskopen vorgestellt, die als Multidetektor-Scanning (MDS) bezeichnet wird und auf dem Prinzip der Image-Scanning-Mikroskopie (ISM) beruht. Mit ISM lässt sich die Auflösung von Fluoreszenzmikroskopen theoretisch verdoppeln. Da ISM einen Flächendetektor voraussetzt, wurden in der Vergangenheit hauptsächlich CCD oder CMOS Kameras als Detektoren eingesetzt. In dieser Arbeit werden anstelle einer Kamera mehrere Einzelphotonendetektoren verwendet und über ein Glasfaserbündel zu einem Flächendetektor kombiniert. Dadurch ist es erstmals möglich, die Methode in Verbindung mit Fluoreszenzlebensdauer-Mikroskopie (FLIM) einzusetzen. FLIM hat sich in den Biowissenschaften als wichtige Mikroskopie-Technik etabliert und wird unter anderem bei Protein-Protein-Interaktionsstudien oder zur Untersuchung des NADH-Metabolismus eingesetzt. Die Verbesserung der räumlichen Auflösung von FLIM mit MDS ist somit für eine Reihe von biologischen Fragestellungen von potentiellem Interesse. Im Rahmen der Arbeit wurde ein Multidetektor-Scanning-Mikroskop konstruiert und durch die Vermessung von fluoreszierenden Mikropartikeln charakterisiert. Eine Verbesserung der Auflösung durch MDS wird an fixierten biologischen Proben demonstriert. Dabei wurde eine Auflösung von 168 nm mit MDS sowie 146 nm mit MDS und Dekonvolution erreicht. Schließlich wird die Kombination der Methode mit Fluoreszenzlebensdauer-Mikroskopie demonstriert. 540 Fluoreszenzmikroskopie Konfokalmikroskopie Fluoreszenzlebensdauer-Mikroskopie Einzelmolekülfluoreszenzspektroskopie fluorescence lifetime imaging microscopy fluorescence microscopy confocal microscopy single molecule fluorescence microscopy Chemie (PPN62138352X)
17	Probing Nanoscale Electrochemical Processes on Single Gold Nanoparticles using Optical Microscopy Molina, Natalia Y., 0000-0001-9555-2761 January 2022 (has links) In this work, we use optical techniques to provide insight into how various components within electrochemical cells can impart apparent heterogeneity to single gold nanoparticle electrodes. Optical methods are advantageous in comparison to traditional electrochemical techniques due to their high sensitivity and spatial resolution, allowing us to study the impact of heterogeneity with single nanoparticle and single molecule sensitivity. Throughout the course of this dissertation, two optical techniques are discussed in detail, dark-field microscopy, and single molecule fluorescence imaging. We first began by studying the impact of the substrate using dark-field microscopy to monitor the electrodissolution kinetics of gold nanoparticles on thin films of tin-doped indium oxide (ITO), which is a commonly used supporting electrode for correlated optical and electrochemical studies. We found that ITO from two different suppliers showed marked differences in the gold electrodissolution kinetics, with ITO from one of the suppliers even showing poor sample-to-sample reproducibility across substrates within the same lot number. These results showed that the supporting electrode cannot be ignored when performing single nanoparticle structure-function studies. In the second work, we analyzed the electrodissolution of gold nanoparticles on well-behaved ITO substrates to investigate heterogeneity in their electrodissolution kinetics. The rate constants associated with the electrodissolution of Au NPs were extracted by fitting the intensity-time traces to a first-order kinetic model. We found that a non-negligible population of Au NPs didn’t fit the predictive kinetics model leading us to further probe whether surface effects play a role in the electrodissolution process. Super-localization imaging was used to track the center position of the Au NPs as they electrodissolved revealing three distinct electrodissolution behaviors, and a mechanism for the electrodissolution of Au NPs was proposed. Furthermore, calcite-assisted localization and kinetics (CLocK) microscopy was used to visualize changes in anisotropy and provide information as to how the shape of the Au NP changes as it electrodissolves. Lastly, in our third work, we provide insight as to how heterogeneity from all the different components of a single nanoparticle electrochemical sample impacts the apparent electrode performance. We proposed dark-field microscopy and single molecule fluorescence imaging as tools capable of detangling these effects. Moreover, we established Cresyl Violet as a reporter of single molecule electrochemistry and developed a two-working electrode optical system capable of visualizing single molecule activity. Lastly, we explored the relationships between Au NP size, Cresyl Violet activity and Au NP electrodissolution and found no clear trend between them suggesting the need for more studies to deconvolute these effects and provide meaningful insight into the structure-property relationships. Overall, this dissertation highlights the complexity of single nanoparticle studies and how heterogeneity can be induced from all the components of an electrochemical cell. / Chemistry Physical chemistry Analytical chemistry Nanoscience Electrochemistry Gold nanoparticles Optical microscopy Single molecule fluorescence Single-entity electrochemistry Tin-doped indium oxide
18	Étude de l'oligomérisation et de la fonction de canaux ioniques par spectroscopie de fluorescence et fluorométrie en voltage imposé McGuire, Hugo 04 1900 (has links) La fonction des canaux ioniques est finement régulée par des changements structuraux de sites clés contrôlant l’ouverture du pore. Ces modulations structurales découlent de l’interaction du canal avec l’environnement local, puisque certains domaines peuvent être suffisamment sensibles à des propriétés physico-chimiques spécifiques. Les mouvements engendrés dans la structure sont notamment perceptibles fonctionnellement lorsque le canal ouvre un passage à certains ions, générant ainsi un courant ionique mesurable selon le potentiel électrochimique. Une description détaillée de ces relations structure-fonction est cependant difficile à obtenir à partir de mesures sur des ensembles de canaux identiques, puisque les fluctuations et les distributions de différentes propriétés individuelles demeurent cachées dans une moyenne. Pour distinguer ces propriétés, des mesures à l’échelle de la molécule unique sont nécessaires. Le but principal de la présente thèse est d’étudier la structure et les mécanismes moléculaires de canaux ioniques par mesures de spectroscopie de fluorescence à l’échelle de la molécule unique. Les études sont particulièrement dirigées vers le développement de nouvelles méthodes ou leur amélioration. Une classe de toxine formeuse de pores a servi de premier modèle d’étude. La fluorescence à l’échelle de la molécule unique a aussi été utilisée pour l’étude d’un récepteur glutamate, d’un récepteur à la glycine et d’un canal potassique procaryote. Le premier volet porte sur l’étude de la stœchiométrie par mesures de photoblanchiment en temps résolu. Cette méthode permet de déterminer directement le nombre de monomères fluorescents dans un complexe isolé par le décompte des sauts discrets de fluorescence suivant les événements de photoblanchiment. Nous présentons ici la première description, à notre connaissance, de l’assemblage dynamique d’une protéine membranaire dans un environnement lipidique. La toxine monomérique purifiée Cry1Aa s’assemble à d’autres monomères selon la concentration et sature en conformation tétramérique. Un programme automatique est ensuite développé pour déterminer la stœchiométrie de protéines membranaires fusionnées à GFP et exprimées à la surface de cellules mammifères. Bien que ce système d’expression soit approprié pour l’étude de protéines d’origine mammifère, le bruit de fluorescence y est particulièrement important et augmente significativement le risque d’erreur dans le décompte manuel des monomères fluorescents. La méthode présentée permet une analyse rapide et automatique basée sur des critères fixes. L’algorithme chargé d’effectuer le décompte des monomères fluorescents a été optimisé à partir de simulations et ajuste ses paramètres de détection automatiquement selon la trace de fluorescence. La composition de deux canaux ioniques a été vérifiée avec succès par ce programme. Finalement, la fluorescence à l’échelle de la molécule unique est mesurée conjointement au courant ionique de canaux potassiques KcsA avec un système de fluorométrie en voltage imposé. Ces enregistrements combinés permettent de décrire la fonction de canaux ioniques simultanément à leur position et densité alors qu’ils diffusent dans une membrane lipidique dont la composition est choisie. Nous avons observé le regroupement de canaux KcsA pour différentes compositions lipidiques. Ce regroupement ne paraît pas être causé par des interactions protéine-protéine, mais plutôt par des microdomaines induits par la forme des canaux reconstitués dans la membrane. Il semble que des canaux regroupés puissent ensuite devenir couplés, se traduisant en ouvertures et fermetures simultanées où les niveaux de conductance sont un multiple de la conductance « normale » d’un canal isolé. De plus, contrairement à ce qui est actuellement suggéré, KcsA ne requiert pas de phospholipide chargé négativement pour sa fonction. Plusieurs mesures indiquent plutôt que des lipides de forme conique dans la phase cristalline liquide sont suffisants pour permettre l’ouverture de canaux KcsA isolés. Des canaux regroupés peuvent quant à eux surmonter la barrière d’énergie pour s’ouvrir de manière coopérative dans des lipides non chargés de forme cylindrique. / The function of ion channels is finely regulated by structural changes of key domains controlling the pore opening. These structural modulations arise from interactions with the local environment, since several domains can be sensitive to specific physico-chemical properties. Movements generated in the structure become notably perceptible when channels open a passage for some ions, thus generating a measurable ionic current according to the electrochemical potential. A detailed description of these structure-function relationships is however difficult to obtain from measurements involving a set of identical channels, since the fluctuations and distributions of different individual properties remain hidden in an average. To differentiate these properties, single-molecule recordings are required. The main purpose of this thesis is to study the structural aspects and molecular mechanisms of ion channels using fluorescence spectroscopy at the single-molecule level. Studies are oriented towards the development or improvement of new methods. A class of pore-forming toxin served as a first study model. Single-molecule fluorescence was also used to study an ionotropic glutamate receptor, a glycine receptor and a prokaryotic potassium channel. The first part focuses on the study of stoichiometry using fluorescent subunit counting. This method allows a direct measure of the number of fluorescent monomers within a single complex by counting the number of step-wise fluorescence intensity decrease following photobleaching events. Here we present the first description, to our knowledge, of the dynamic assembly of a membrane protein in a lipid environment. The purified monomeric Cry1Aa toxin clusters with other monomers depending on the concentration and saturates in a tetrameric conformation. An automated method has been developed to determine the stoichiometry of GFP-tagged membrane proteins expressed on mammalian cell surface. Although this expression system is suitable for the study of proteins of mammalian origin, background fluorescence is particularly important and significantly increases the risk of error in the manual counting process. The presented method allows a fast and automated analysis based on fixed criteria. The algorithm responsible for counting fluorescent monomers was optimized from simulations and adjusts its detection parameters automatically according to the fluorescence trace recording. The composition of two ion channels was successfully verified using this program. Finally, single-molecule fluorescence is measured together with ionic current of KcsA channels using a voltage-clamp fluorometry setup. These combined recordings allowed us to describe the function of ion channels simultaneously to their position and density as they diffuse in a lipid membrane of defined composition. We observed clustering of KcsA channels for various lipid compositions. Clustering does not appear to be caused by protein-protein interaction, but rather by microdomains induced by the shape of reconstructed channels in the lipid bilayer. It seems that clustered KcsA channels could then become coupled, resulting in cooperative gating events with conductance levels multiple to the “normal” unitary channel conductance. Moreover, as opposed to what is currently suggested, KcsA does not require a negatively charged phospholipid for its function. Several of our recordings rather suggest that conically shaped lipids in the lamellar liquid crystalline phase are sufficient to allow single channel opening. Clustered channels can on the other hand overcome the energy barrier to open cooperatively in uncharged cylindrical lipids. Fluorescence de la molécule unique Fluorométrie en voltage imposé Canaux ioniques Single-molecule fluorescence Voltage-clamp fluorometry Ion channels
19	Development of a single-molecule tracking assay for the lac repressor in Escherichia coli Broström, Oscar January 2019 (has links) Gene regulation by transcription factors are one of the key processes that are important to sustain all kinds of life. In the prokaryote Escherichia coli this has shown to especially crucial. The operator sequence to which these transcription factors bind to are very small in comparison to the whole genome of E. coli, thus the question becomes how these proteins can find these sequences quickly. One particularly well-studied transcription factor in this regard is the lac repressor. It has been shown that this transcription factors finds its operators faster than the limit of three dimensional diffusion. The leading model for how the repressor does that is facilitated diffusion and this model has gained more experimental evidence, particularly using single-molecule fluorescence microscopy. This study aimed at measuring the unspecific binding time between the lac repressor and DNA in vivo, but in the end the project evolved to trying to establish a single-molecule tracking assay of the repressor in vivo. In this study a mutant of the repressor was expressed and purified, labelled with a synthetic fluorophore, electroporated into E. coli and tracking was performed under a microscope. One of the three types of experiments were partially analysed with an image analysis software. Unfortunately, analysis was not completed for all experiments which made it difficult to compare the results. In the end the data was compared by eye while also using the results from image analysis. With slight optimism it can be concluded that the assay worked, but it needs more development. Escherichia Coli Single-molecule fluorescence microscopy In vivo tracking In vivo lac repressor LacI Bifunctional rhodamine B E. coli In vivo Engineering and Technology Teknik och teknologier
20	Single-molecule experiments with mitotic motor proteins / Einzelmolekül-Experimente mit mitotischen Motorproteinen Thiede, Christina 28 September 2012 (has links) No description available. 530 Physik WCC 000 Physics Einzelmolekül-Fluoreszenzmikroskopie TIRF-Mikroskopie mitotische Motorproteine Kinesin-5 Regulation single-molecule fluorescence microscopy TIRF microscopy mitotic motor proteins Kinesin-5 regulation 42.12

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