TY  - THES
A1  - Klein, Teresa
T1  - Lokalisationsmikroskopie für die Visualisierung zellulärer Strukturen
T1  - Localization Microscopy for the visualization of cellular structures
N2  - Die Einführung der Fluoreszenzmikroskopie ermöglicht es, Strukturen in Zellen spezifisch und mit hohem Kontrast zu markieren und zu untersuchen. Da die Lichtmikroskopie jedoch in ihrer Auflösung begrenzt ist, bleiben Strukturinformationen auf molekularer Ebene verborgen. Diese als Beugungsgrenze bekannte Limitierung, kann mit modernen Verfahren umgangen werden. Die Lokalisationsmikroskopie nutzt hierfür photoschaltbare Fluorophore, deren Fluoreszenz räumlich und zeitlich separiert wird, um so einzelne Fluorophore mit
Nanometer-Genauigkeit lokalisieren zu können. Aus tausenden Einzelmolekül-Lokalisationen wird ein künstliches, hochaufgelöstes Bild rekonstruiert. Die
hochauflösende Mikroskopie ist grade für die Lebendzell-Beobachtung ein wertvolles Werkzeug, um subzelluläre Strukturen und Proteindynamiken jenseits der Beugungsgrenze unter physiologischen Bedingungen untersuchen zu können.
Als Marker können sowohl photoaktivierbare fluoreszierende Proteine als auch photoschaltbare organische Fluorophore eingesetzt werden. Während die
Markierung mit fluoreszierenden Proteinen einfach zu verwirklichen ist, haben organische Farbstoffe hingegen den Vorteil, dass sie auf Grund der höheren Photonenausbeute eine präzisere Lokalisation erlauben. In lebenden Zellen wird die Markierung von Strukturen mit synthetischen Fluorophoren über sogenannte
chemische Tags ermöglicht. Diese sind olypeptidsequenzen, die genetisch an das Zielprotein fusioniert werden und anschließend mit Farbstoff-gekoppelten Substraten gefärbt werden. An der Modellstruktur des Histonproteins H2B
werden in dieser Arbeit Farbstoffe in Kombination mit chemischen Tags identifiziert, die erfolgreich für die Hochauflösung mit direct stochastic optical
reconstruction microscopy (dSTORM) in lebenden Zellen eingesetzt werden können. Für besonders geeignet erweisen sich die Farbstoffe Tetramethylrhodamin,
505 und Atto 655, womit der gesamte spektrale Bereich vertreten ist. Allerdings können unspezifische Bindung und Farbstoffaggregation ein Problem bei der effizienten Markierung in lebenden Zellen darstellen. Es wird
gezeigt, dass die Beschichtung der Glasoberfläche 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 Photoschädigung möglichst gering zu halten, beispielsweise
durch die Wahl eines Farbstoffs im rotem Anregungsbereich.
Die Möglichkeit lebende Zellen mit photoschaltbaren organischen Fluorophoren spezifisch markieren zu können, stellt einen großen Gewinn für die Lokalisationsmikroskopie dar, bei der ursprünglich farbstoffgekoppelte Antikörper 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 aufgeklärt. Dabei wird gezeigt, dass intrazellulär vorhandene Peptide größere Aggregate formen als die im extrazellulären 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.
N2  - The implementation of fluorescence microscopy enables specific labeling and studying of cellular structures with high contrast. Since light microscopy is limited in its resolution, structural information at the molecular level remains hidden. This barrier, known as diffraction limit, can be circumvented by modern imaging techniques. For this purpose localization microscopy employs photoswitchable fluorophores. The fluorescence of these fluorophores is spatially and temporally separated in order to localize single fluorophores with nanometer
precision. From thousands of single-molecule localizations an artificial highresolution image is reconstructed. Super-resolution microscopy is a valuable
tool for live-cell observations in order to investigate sub-cellular structures and protein dynamics beyond the diffraction limit under physiological conditions.
Both photoactivatable fluorescent proteins and photoswitchable organic fluorophores can be used as labels. Whereas labeling with fluorescent proteins is
straightforward to implement, organic fluorophores, however, have the Advantage of a more precise localization due to a higher photon yield. In living cells, labeling of structures with synthetic fluorophores is facilitated by so-called chemical tags. Those are polypeptide sequences that are genetically fused to
the target protein and subsequently labeled with dye coupled substrates. In this work, on the basis of the model structure H2B—a histone protein—dyes
are identified in combination with chemical tags, that can be successfully used for super-resolution imaging with direct stochastic optical reconstruction
microscopy (dSTORM) in living cells. The dyes tetramethylrhodamine, 505 and Atto 655 proved to be particularly suitable, whereby the whole spectral
range is represented. However, unspecific binding and dye aggregation can pose a problem for the efficient labeling of living cells. It is shown, that coating the glass surface with glycine successfully minimizes unspecific adsorption of fluorophores. Furthermore the impact of the excitation light on living cells is discussed. Methods are presented to keep photodamage at a minimum, e. g.,
by choosing a dye within the red excitation range.
The feasibility to label living cells with photoswitchable organic fluorophores represents a big asset for localization microscopy, which originally employed dye labeled antibodies. This alternative labeling technique is used in a collaboration
to study the aggregation behavior of � -Amyloid peptides, which cause Alzheimer’s disease. By means of HeLa cells, different diffraction limited morphologies of aggregates are revealed. It is thereby shown, that intracellular
peptides generate larger aggregates than the ones in the extracellular region. In another collaboration the structural organization of two flotillin proteins in
the membrane of bacteria is examined by means of the photoactivatable Protein mEos2 and photoactivated localization microscopy (PALM). These proteins
form two clusters with different diameters, which could be determined with nanometer precision. It was also asserted that both proteins exist in unequal
numbers within the bacterium.
KW  - Hochauflösendes Verfahren
KW  - Zellmarker
KW  - dSTORM
KW  - PALM
KW  - live-cell
KW  - Hochauflösung
KW  - Zellmarkierung
Y1  - 2014
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-99260
ER  - 
TY  - JOUR
A1  - Andronic, Joseph
A1  - Shirakashi, Ryo
A1  - Pickel, Simone U.
A1  - Westerling, Katherine M.
A1  - Klein, Teresa
A1  - Holm, Thorge
A1  - Sauer, Markus
A1  - Sukhorukov, Vladimir L.
T1  - Hypotonic Activation of the Myo-Inositol Transporter SLC5A3 in HEK293 Cells Probed by Cell Volumetry, Confocal and Super-Resolution Microscopy
JF  - PLoS One
N2  - Swelling-activated pathways for myo-inositol, one of the most abundant organic osmolytes in mammalian cells, have not yet been identified. The present study explores the SLC5A3 protein as a possible transporter of myo-inositol in hyponically swollen HEK293 cells. To address this issue, we examined the relationship between the hypotonicity-induced changes in plasma membrane permeability to myo-inositol Pino [m/s] and expression/localization of SLC5A3. Pino values were determined by cell volumetry over a wide tonicity range (100–275 mOsm) in myo-inositol-substituted solutions. While being negligible under mild hypotonicity (200–275 mOsm), Pino grew rapidly at osmolalities below 200 mOsm to reach a maximum of ∼3 nm/s at 100–125 mOsm, as indicated by fast cell swelling due to myo-inositol influx. The increase in Pino resulted most likely from the hypotonicity-mediated incorporation of cytosolic SLC5A3 into the plasma membrane, as revealed by confocal fluorescence microscopy of cells expressing EGFP-tagged SLC5A3 and super-resolution imaging of immunostained SLC5A3 by direct stochastic optical reconstruction microscopy (dSTORM). dSTORM in hypotonic cells revealed a surface density of membrane-associated SLC5A3 proteins of 200–2000 localizations/μm2. Assuming SLC5A3 to be the major path for myo-inositol, a turnover rate of 80–800 myo-inositol molecules per second for a single transporter protein was estimated from combined volumetric and dSTORM data. Hypotonic stress also caused a significant upregulation of SLC5A3 gene expression as detected by semiquantitative RT-PCR and Western blot analysis. In summary, our data provide first evidence for swelling-mediated activation of SLC5A3 thus suggesting a functional role of this transporter in hypotonic volume regulation of mammalian cells.
KW  - electrolytes
KW  - isotonic
KW  - membrane proteins
KW  - cell membranes
KW  - hypotonic
KW  - hypotonic solutions
KW  - tonicity
KW  - permeability
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-126408
VL  - 10
IS  - 3
ER  - 
TY  - JOUR
A1  - Schneider, Johannes
A1  - Klein, Teresa
A1  - Mielich-Süss, Benjamin
A1  - Koch, Gudrun
A1  - Franke, Christian
A1  - Kuipers, Oskar P.
A1  - Kovács, Ákos T.
A1  - Sauer, Markus
A1  - Lopez, Daniel
T1  - Spatio-temporal Remodeling of Functional Membrane Microdomains Organizes the Signaling Networks of a Bacterium
JF  - PLoS Genetics
N2  - Lipid rafts are membrane microdomains specialized in the regulation of numerous cellular processes related to membrane organization, as diverse as signal transduction, protein sorting, membrane trafficking or pathogen invasion. It has been proposed that this functional diversity would require a heterogeneous population of raft domains with varying compositions. However, a mechanism for such diversification is not known. We recently discovered that bacterial membranes organize their signal transduction pathways in functional membrane microdomains (FMMs) that are structurally and functionally similar to the eukaryotic lipid rafts. In this report, we took advantage of the tractability of the prokaryotic model Bacillus subtilis to provide evidence for the coexistence of two distinct families of FMMs in bacterial membranes, displaying a distinctive distribution of proteins specialized in different biological processes. One family of microdomains harbors the scaffolding flotillin protein FloA that selectively tethers proteins specialized in regulating cell envelope turnover and primary metabolism. A second population of microdomains containing the two scaffolding flotillins, FloA and FloT, arises exclusively at later stages of cell growth and specializes in adaptation of cells to stationary phase. Importantly, the diversification of membrane microdomains does not occur arbitrarily. We discovered that bacterial cells control the spatio-temporal remodeling of microdomains by restricting the activation of FloT expression to stationary phase. This regulation ensures a sequential assembly of functionally specialized membrane microdomains to strategically organize signaling networks at the right time during the lifespan of a bacterium.
KW  - membrane proteins
KW  - gene expression
KW  - bacillus subtilis
KW  - fluorescence microscopy
KW  - cell fusion
KW  - signal transduction
KW  - gene regulation
KW  - lipids
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-125577
VL  - 11
IS  - 4
ER  - 
TY  - JOUR
A1  - Wäldchen, Sina
A1  - Lehmann, Julian
A1  - Klein, Teresa
A1  - van de Linde, Sebastian
A1  - Sauer, Markus
T1  - Light-induced cell damage in live-cell super-resolution microscopy
JF  - Scientific Reports
N2  - Super-resolution microscopy can unravel previously hidden details of cellular structures but requires high irradiation intensities to use the limited photon budget efficiently. Such high photon densities are likely to induce cellular damage in live-cell experiments. We applied single-molecule localization microscopy conditions and tested the influence of irradiation intensity, illumination-mode, wavelength, light-dose, temperature and fluorescence labeling on the survival probability of different cell lines 20-24 hours after irradiation. In addition, we measured the microtubule growth speed after irradiation. The photo-sensitivity is dramatically increased at lower irradiation wavelength. We observed fixation, plasma membrane permeabilization and cytoskeleton destruction upon irradiation with shorter wavelengths. While cells stand light intensities of similar to 1 kW cm\(^{-2}\) at 640 nm for several minutes, the maximum dose at 405 nm is only similar to 50 J cm\(^{-2}\), emphasizing red fluorophores for live-cell localization microscopy. We also present strategies to minimize phototoxic factors and maximize the cells ability to cope with higher irradiation intensities.
KW  - optical reconstruction microscopy
KW  - tag fusion proteins
KW  - localization microscopy
KW  - photodynamic therapy
KW  - diffraction limit
KW  - illumination microscopy
KW  - structured illumination
KW  - fluorescent probes
KW  - in vitro
KW  - dynamics
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-145207
VL  - 5
IS  - 15348
ER  - 
TY  - JOUR
A1  - Grimm, Jonathan B.
A1  - Klein, Teresa
A1  - Kopek, Benjamin G.
A1  - Shtengel, Gleb
A1  - Hess, Harald F.
A1  - Sauer, Markus
A1  - Lavis, Luke D.
T1  - Synthesis of a far-red photoactivatable silicon-containing rhodamine for super-resolution microscopy
JF  - Angewandte Chemie International Edition
N2  - The rhodamine system is a flexible framework for building small‐molecule fluorescent probes. Changing N‐substitution patterns and replacing the xanthene oxygen with a dimethylsilicon moiety can shift the absorption and fluorescence emission maxima of rhodamine dyes to longer wavelengths. Acylation of the rhodamine nitrogen atoms forces the molecule to adopt a nonfluorescent lactone form, providing a convenient method to make fluorogenic compounds. Herein, we take advantage of all of these structural manipulations and describe a novel photoactivatable fluorophore based on a Si‐containing analogue of Q‐rhodamine. This probe is the first example of a “caged” Si‐rhodamine, exhibits higher photon counts compared to established localization microscopy dyes, and is sufficiently red‐shifted to allow multicolor imaging. The dye is a useful label for super‐resolution imaging and constitutes a new scaffold for far‐red fluorogenic molecules.
KW  - fluorophore
KW  - microscopy
KW  - photoactivation
KW  - Si-rhodamine
KW  - super-resolution imaging
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-191069
VL  - 55
IS  - 5
ER  -