@phdthesis{Proppert2014,
  author    = {Proppert, Sven Martin},
  title     = {Design, implementation and characterization of a microscope capable of three-dimensional two color super-resolution fluorescence imaging},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-107905},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2014},
  abstract  = {This thesis reviews the fundamentals of three-dimensional super-resolution localization imaging. In order to infer the axial coordinate of the emission of single fluorophores, the point spread function is engineered following a technique usually referred to as astigmatic imaging by the introduction of a cylindrical lens to the detection path of a microscope. After giving a short introduction to optics and localization microscopy, I outline sources of aberrations as frequently encountered in 3D-localization microscopy and will discuss their respective impact on the precision and accuracy of the localization process. With the knowledge from these considerations, experiments were designed and conducted to verify the validity of the conclusions and to demonstrate the abilities of the proposed microscope to resolve biological structures in the three spatial dimensions. Additionally, it is demonstrated that measurements of huge volumes with virtually no aberrations is in principle feasible. During the course of this thesis, a new method was introduced for inferring axial coordinates. This interpolation method based on cubic B-splines shows superior performance in the calibration of a microscope and the evaluation of subsequent measurement and will therefore be used and explained in this work. Finally, this work is also meant to give future students some guidance for entering the field of 3D localization microscopy and therefore, detailed protocols are provided covering the specific aspects of two color 3D localization imaging.},
  subject      = {Dimension 3},
  language  = {en}
}
@phdthesis{Klein2014,
  author    = {Klein, Teresa},
  title     = {Lokalisationsmikroskopie f{\"u}r die Visualisierung zellul{\"a}rer Strukturen},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-99260},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2014},
  abstract  = {Die Einf{\"u}hrung der Fluoreszenzmikroskopie erm{\"o}glicht es, Strukturen in Zellen spezifisch und mit hohem Kontrast zu markieren und zu untersuchen. Da die Lichtmikroskopie jedoch in ihrer Aufl{\"o}sung begrenzt ist, bleiben Strukturinformationen auf molekularer Ebene verborgen. Diese als Beugungsgrenze bekannte Limitierung, kann mit modernen Verfahren umgangen werden. Die Lokalisationsmikroskopie nutzt hierf{\"u}r photoschaltbare Fluorophore, deren Fluoreszenz r{\"a}umlich und zeitlich separiert wird, um so einzelne Fluorophore mit Nanometer-Genauigkeit lokalisieren zu k{\"o}nnen. Aus tausenden Einzelmolek{\"u}l-Lokalisationen wird ein k{\"u}nstliches, hochaufgel{\"o}stes Bild rekonstruiert. Die hochaufl{\"o}sende Mikroskopie ist grade f{\"u}r die Lebendzell-Beobachtung ein wertvolles Werkzeug, um subzellul{\"a}re Strukturen und Proteindynamiken jenseits der Beugungsgrenze unter physiologischen Bedingungen untersuchen zu k{\"o}nnen. Als Marker k{\"o}nnen sowohl photoaktivierbare fluoreszierende Proteine als auch photoschaltbare organische Fluorophore eingesetzt werden. W{\"a}hrend die Markierung mit fluoreszierenden Proteinen einfach zu verwirklichen ist, haben organische Farbstoffe hingegen den Vorteil, dass sie auf Grund der h{\"o}heren Photonenausbeute eine pr{\"a}zisere Lokalisation erlauben. In lebenden Zellen wird die Markierung von Strukturen mit synthetischen Fluorophoren {\"u}ber sogenannte chemische Tags erm{\"o}glicht. Diese sind olypeptidsequenzen, die genetisch an das Zielprotein fusioniert werden und anschließend mit Farbstoff-gekoppelten Substraten gef{\"a}rbt werden. An der Modellstruktur des Histonproteins H2B werden in dieser Arbeit Farbstoffe in Kombination mit chemischen Tags identifiziert, die erfolgreich f{\"u}r die Hochaufl{\"o}sung mit direct stochastic optical reconstruction microscopy (dSTORM) in lebenden Zellen eingesetzt werden k{\"o}nnen. F{\"u}r besonders geeignet erweisen sich die Farbstoffe Tetramethylrhodamin, 505 und Atto 655, womit der gesamte spektrale Bereich vertreten ist. Allerdings k{\"o}nnen unspezifische Bindung und Farbstoffaggregation ein Problem bei der effizienten Markierung in lebenden Zellen darstellen. Es wird gezeigt, dass die Beschichtung der Glasoberfl{\"a}che mit Glycin die unspezifische Adsorption der Fluorophore erfolgreich minimieren kann. Weiterhin wird der Einfluss des Anregungslichtes auf die lebende Zelle diskutiert. Es werden Wege beschrieben, um die Photosch{\"a}digung m{\"o}glichst gering zu halten, beispielsweise durch die Wahl eines Farbstoffs im rotem Anregungsbereich. Die M{\"o}glichkeit lebende Zellen mit photoschaltbaren organischen Fluorophoren spezifisch markieren zu k{\"o}nnen, stellt einen großen Gewinn f{\"u}r die Lokalisationsmikroskopie dar, bei der urspr{\"u}nglich farbstoffgekoppelte Antik{\"o}rper zum Einsatz kamen. Diese Markierungsmethode wird in dieser Arbeit eingesetzt, um das Aggregationsverhalten von Alzheimer verursachenden � -Amyloid Peptiden im Rahmen einer Kooperation zu untersuchen. Es werden anhand von HeLa Zellen verschiedene beugungsbegrenzte Morphologien der Aggregate aufgekl{\"a}rt. Dabei wird gezeigt, dass intrazellul{\"a}r vorhandene Peptide gr{\"o}ßere Aggregate formen als die im extrazellul{\"a}ren Bereich. In einer zweiten Kollaboration wird mit Hilfe des photoaktivierbaren Proteins mEos2 und photoactivated localization microscopy (PALM) die strukturelle Organisation zweier Flotillinproteine in der Membran von Bakterien untersucht. Diese Proteine bilden zwei Cluster mit unterschiedlichen Durchmessern, die mit Nanometer-Genauigkeit bestimmt werden konnten. Es wurde außerdem festgestellt, dass beide Proteine in unterschiedlichen Anzahlen im Bakterium vorliegen.},
  subject      = {Hochaufl{\"o}sendes Verfahren},
  language  = {de}
}
@phdthesis{Heidbreder2012,
  author    = {Heidbreder, Meike},
  title     = {Association and Activation of TNF-Receptor I Investigated with Single-Molecule Tracking and Super-Resolution Microscopy in Live Cells},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-73191},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2012},
  abstract  = {Cellular responses to outer stimuli are the basis for all biological processes. Signal integration is achieved by protein cascades, recognizing and processing molecules from the environment. Factors released by pathogens or inflammation usually induce an inflammatory response, a signal often transduced by Tumour Necrosis Factor alpha (TNF). TNFα receptors TNF-R1 and TNF-R2 can in turn lead to apoptosis or proliferation via NF-B. These processes are closely regulated by membrane compartimentalization, protein interactions and trafficking. Fluorescence microscopy offers a reliable and non-invasive method to probe these cellular events. However, some processes on a native membrane are not resolvable, as they are well below the diffraction limit of microscopy. The recent development of super-resolution fluorescence microscopy methods enables the observation of these cellular players well below this limit: by localizing, tracking and counting molecules with high spatial and temporal resolution, these new fluorescence microscopy methods offer a previously unknown insight into protein interactions at the near-molecular level. Direct stochastic optical reconstruction microscopy (dSTORM) utilizes the reversible, stochastic blinking events of small commercially available fluorescent dyes, while photoactivated localization microscopy (PALM) utilizes phototransformation of genetically encoded fluorescent proteins. By photoactivating only a small fraction of the present fluorophores in each observation interval, single emitters can be localized with high precision and a super-resolved image can be reconstructed. Quantum Dot Triexciton imaging (QDTI) utilizes the three-photon absorption (triexcitonic) properties of quantum dots (QD) and to achieve a twofold resolution increase using conventional confocal microscopes. In this thesis, experimental approaches were implemented to achieve super-resolution microscopy in fixed and live-cells to study the spatial and temporal dynamics of TNF and other cellular signaling events. We introduce QDTI to study the three-dimensional cellular distribution of biological targets, offering an easy method to achieve resolution enhancement in combination with optical sectioning, allowing the preliminary quantification of labeled proteins. As QDs are electron dense, QDTI can be used for correlative fluorescence and transmission electron microscopy, proving the versatility of QD probes. Utilizing the phototransformation properties of fluorescent proteins, single-receptor tracking on live cells was achieved, applying the concept of single particle tracking PALM (sptPALM) to track the dynamics of a TNF-R1-tdEos chimera on the membrane. Lateral receptor dynamics can be tracked with high precision and the influences of ligand addition or lipid disruption on TNF-R1 mobility was observed. The results reveal complex receptor dynamics, implying internalization processes in response to TNFα stimulation and a role for membrane domains with reduced fluidity, so-called lipid raft domains, in TNF-R1 compartimentalization prior or post ligand induction. Comparisons with previously published FCS data show a good accordance, but stressing the increased data depth available in sptPALM experiments. Additionally, the active transport of NF-κB-tdEos fusions was observed in live neurons under chemical stimulation and/or inhibition. Contrary to phototransformable proteins that need no special buffers to exhibit photoconversion or photoactivation, dSTORM has previously been unsuitable for in vivo applications, as organic dyes relied on introducing the probes via immunostaining in concert with a reductive, oxygen-free medium for proper photoswitching behaviour. ATTO655 had been previously shown to be suitable for live-cell applications, as its switching behavior can be catalyzed by the reductive environment of the cytoplasm. By introducing the cell-permeant organic dye via a chemical tag system, a high specificity and low background was achieved. Here, the labeled histone H2B complex and thus single nucleosome movements in a live cell can be observed over long time periods and with ~20 nm resolution. Implementing these new approaches for imaging biological processes with high temporal and spatial resolution provides new insights into the dynamics and spatial heterogeneities of proteins, further elucidating their function in the organism and revealing properties that are usually only detectable in vitro.  },
  subject      = {Fluoreszenzmikrosopie},
  language  = {en}
}