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Stickstoffmonoxid (NO) ist ein gasförmiges, relativ stabiles Radikal, das in Pflanzen u. a. durch Reduktion aus Nitrit unter Katalyse des Enzyms Nitratreduktase gebildet wird. In tierischen Organismen wird NO dagegen über einen oxidativen Syntheseweg aus der Ami-nosäure L-Arginin katalysiert durch verschiedene Isoformen der NO-Synthasen (NOS) hergestellt. Es besitzt im tierischen System vielfältige Funktionen u. a. als Neurotransmitter sowie Blutfluss und -druck regulierendes Agens. Im Pflanzenreich werden NO u. a. Aufgaben bei der Regulierung von Spaltöffnungen, der Abwehr von Pathogenen sowie der Differenzierung der Xylemelemente zugeschrieben. Die vorliegende Arbeit verfolgte zwei Ziele: - Erforschung alternativer oxidativer Synthesewege von NO in Pflanzen und - Untersuchung der NO-Spezifität der DAF-Fluoreszenzfarbstoffe ausgehend Diskrepanzen zwischen Daten aus Floureszenzanalysen und der Gasphasen-Chemilumineszenz in früheren Arbeiten unserer Arbeitsgruppe und zahlreichen weiteren Publikationen. a) NO-Produktion aus Hydroxylaminen Hydroxylamin ist ein Zwischenprodukt bei der bakteriellen Denitrifizierung und wurde auch als Intermediat bei der Nitratreduktion in Pflanzen diskutiert. Hier wird gezeigt, dass Tabaksuspensionzellen in der Lage waren, exogenes Hydroxylamin schon in sehr niedrigen Konzentrationen (4 µM) zu NO zu oxidieren. Auch ein anderes HA-Derivat, nämlich der Hemmstoff der Alternativen Oxidase (AOX) in Mitochondrien, Salicylhydroxamsäure (SHAM), wurde zu NO oxidiert. Die Vermutung, reaktive Sauerstoffspezies (ROS) könn-ten bei diesem Oxidationsprozess eine Rolle spielen, wurde überprüft: Nach Einwirkung des ROS-abbauenden Enzyms Superoxid-Dismutase (SOD) konnte aber überraschender-weise keine Verminderung, sondern eher eine Steigerung der NO-Emission beobachtet werden. Die Rolle der SOD in diesem Reaktionsprozess ist daher noch nicht verstanden. b) NO-Detektion mittels Fluoreszenzindikatoren Zur Visualisierung und Lokalisierung von NO in tierischen und pflanzlichen Zellen und Geweben (in situ) mittels mikroskopischer (LSM) oder fluorimetrischer Methoden werden Fluoreszenzfarbstoffe, z. B. DAF-2 oder DAF-FM verwendet. Diese Farbstoffe reagieren mit NO zu stark fluoreszierenden Triazol-Derivaten. Eine Situation, in der Pflanzen u. a. mit NO-Freisetzung reagieren, ist der Pathogenbefall. Wir untersuchten die Reaktion von Tabaksuspensionszellen auf den pilzlichen Elicitor Cryptogein, ein Protein des Oomyceten Phytophthora cryptogea. Im Filtrat der Zellen, die mit Cryptogein behandelt wurden, zeigte sich nach Zugabe von DAF-Farbstoffen ein starker Fluoreszenzanstieg. Um die fluoreszenzerhöhenden Stoffe zu charakterisieren, wurde das Filtrat vor der DAF-Zugabe verschiedentlich behandelt. Bei Zugabe von KCN bzw. Katalase zum Überstand, verringerte sich der Fluoreszenzanstieg. Gleichzeitige Behandlung der Zellen mit Cryptogein sowie dem NADPH-Oxidase-Inhibitor DPI unterband den Fluoreszenzanstieg im Überstand nahezu komplett. Enzym-Assays mit Amplex Rot zeigten die Anhäufung von H2O2 im Filtrat der elicitierten Zellen. Neben ROS werden von Pflanzenzellen auch Peroxidasen in den Apoplasten sekretiert, die mit Hilfe von H2O2 für eine verstärkte Quervernetzung der Zellwand sorgen. Sowohl in unbehandelten Kontrollzellen als auch in elicitierten Zellen wurde Peroxidase-Aktivität nachgewiesen. Nach Zugabe von H2O2 und DAF-2 zum Filtrat von Kontrollzellen ergab sich ein Fluoreszenzanstieg ähnlich dem im Filtrat von behandelten Zellen. Mit Hilfe eines einfachen In-vitro-Systems aus Meerettich-Peroxidase (MR-PO), Wasser-stoffperoxid (H2O2) und DAF-2 konnten noch höhere Fluoreszenzwerte erzielt werden, was die Vermutung der Fluoreszenzerhöhung ohne Anwesenheit von NO erhärtete. Um diese nicht aus einer Reaktion mit NO resultierenden DAF-Produkte näher zu charak-terisieren, wurden Trennungen mittels Umkehrphasen-Hochdruck-Flüssigkeitschro-matographie mit Fluoreszenzdetektion (RP-HPLC-FL) und Massenspektrometrie (UPLC-MS) durchgeführt. Dabei wurden tatsächlich zwei neue Reaktionsprodukte festgestellt, die sich eindeutig von DAF-2T unterschieden. Letzteres konnte nur bei Hinzufügen des NO-Donors DEA-NO detektiert werden. Zur Erfassung von intrazellulären Reaktionsprodukten von DAF wurden die chromatogra-phischen Trennmethoden auch auf Extrakte von mit DAF-2 DA aufgeladenen und danach elicitierten Zellen angewandt. Bei dieser Auftrennung tauchten noch mehr DAF-Reaktionsprodukte auf. Die Hauptfluoreszenz, die auch bei nicht inkubierten Zellen auf-trat, konnte auf eine Reihe sehr früh eluierender Substanzen zurückgeführt werden. Die zwei DAF-Derivate aus dem Überstand inkubierter Zellen bzw. der In-vitro-Reaktion (MR-PO+H2O2+DAF-2) tauchten jedoch überhaupt nicht auf. Vorläufige massenspektrometrische Analysen legen nahe, dass es sich bei den in Abwe-senheit von NO gebildeten zwei Verbindungen um isomere Dimere von DAF-2 handelt.
Novel dyes were prepared by simple “click CuAAC” attachment of a triarylborane–alkyne to the azide side chain of an amino acid yielding triarylborane dye 1 which was conjugated with pyrene (dye 2) forming a triarylborane–pyrene FRET pair. In contrast to previous cationic triarylboranes, the novel neutral dyes interact only with proteins, while their affinity to DNA/RNA is completely abolished. Both the reference triarylborane amino acid and triarylborane–pyrene conjugate bind to BSA and the hDPP III enzyme with high affinities, exhibiting a strong (up to 100-fold) fluorescence increase, whereby the triarylborane–pyrene conjugate additionally retained FRET upon binding to the protein. Furthermore, the triarylborane dyes, upon binding to the hDPP III enzyme, did not impair its enzymatic activity under a wide range of experimental conditions, thus being the first non-covalent fluorimetric markers for hDPP III, also applicable during enzymatic reactions with hDPP III substrates.
Two different chromophores, namely a dipolar and an octupolar system, were prepared and their linear and nonlinear optical properties as well as their bioimaging capabilities were compared. Both contain triphenylamine as the donor and a triarylborane as the acceptor, the latter modified with cationic trimethylammonio groups to provide solubility in aqueous media. The octupolar system exhibits a much higher two‐photon brightness, and also better cell viability and enhanced selectivity for lysosomes compared with the dipolar chromophore. Furthermore, both dyes were applied in two‐photon excited fluorescence (TPEF) live‐cell imaging.
Activating delayed fluorescence emission in a dilute solution via a non-covalent approach is a formidable challenge. In this report, we propose a strategy for efficient delayed fluorescence generation in dilute solution using a non-covalent approach via supramolecularly engineered cyclophane-based nanoenvironments that provide sufficient binding strength to π-conjugated guests and that can stabilize triplet excitons by reducing vibrational dissipation and lowering the singlet–triplet energy gap for efficient delayed fluorescence emission. Toward this goal, a novel biphenyl bisimide-derived cyclophane is introduced as an electron-deficient and efficient triplet-generating host. Upon encapsulation of various carbazole-derived guests inside the nanocavity of this cyclophane, emissive charge transfer (CT) states close to the triplet energy level of the biphenyl bisimide are generated. The experimental results of host–guest studies manifest high association constants up to 10\(^4\) M\(^{–1}\) as the prerequisite for inclusion complex formation, the generation of emissive CT states, and triplet-state stabilization in a diluted solution state. By means of different carbazole guest molecules, we could realize tunable delayed fluorescence emission in this carbazole-encapsulated biphenyl bisimide cyclophane in methylcyclohexane/carbon tetrachloride solutions with a quantum yield (QY) of up to 15.6%. Crystal structure analyses and solid-state photophysical studies validate the conclusions from our solution studies and provide insights into the delayed fluorescence emission mechanism.
Temperature-responsive luminescent solar concentrators (LSCs) have been fabricated in which the Förster resonance energy transfer (FRET) between a donor–acceptor pair in a liquid crystalline solvent can be tuned. At room temperatures, the perylene bisimide (PBI) acceptor is aggregated and FRET is inactive; while after heating to a temperature above the isotropic phase of the liquid crystal solvent, the acceptor PBI completely dissolves and FRET is activated. This unusual temperature control over FRET was used to design a color-tunable LSC. The device has been shown to be highly stable towards consecutive heating and cooling cycles, making it an appealing device for harvesting otherwise unused solar energy.
Bisdiynes undergo Pd(0)-catalyzed cyclization, forming azulene and naphthalene products. When dibenzylideneacetone is present in the reaction, it undergoes a [2+2+2] cyclization with the bisdiyne, forming cyclohexadiene derivatives. Ni(0) catalyzes the [2+2+2] cycloaddition of diynes with tolanes towards alkynylated o-terphenyl derivatives. The D-A substituted products are solvatochromic, fluorescent dyes with high quantum yields and short lifetimes. Bis-triarylborane tetrayne dyes were synthesized in both neutral and tetracationic forms, as potential DNA/RNA sensor. Both molecules are weakly fluorescent in solution and exhibit characteristic alkyne absorptions in the Raman spectra. Tributyl phosphine catalyzes the trans-hydroboration of 1,3-butadiynes with HBpin. We confirmed experimentally via NMR and HRMS experiments, that phosphine attack on the diyne is a key step in the catalytic cycle.
The solvatochromic behavior of two donor-π bridge-acceptor (D-π-A) compounds based on the 2-(3-boryl-2-thienyl)thiazole π-linker and indandione acceptor moiety are investigated. DFT/TD-DFT calculations were performed in combination with steady-state absorption and emission measurements, along with electrochemical studies, to elucidate the effect of two different strongly electron-donating hydrazonyl units on the solvatochromic and fluorescence behavior of these compounds. The Lippert–Mataga equation was used to estimate the change in dipole moments (Δµ) between ground and excited states based on the measured spectroscopic properties in solvents of varying polarity with the data being supported by theoretical studies. The two asymmetrical D-π-A molecules feature strong solvatochromic shifts in fluorescence of up to ~4300 cm\(^{−1}\) and a concomitant change of the emission color from yellow to red. These changes were accompanied by an increase in Stokes shift to reach values as large as ~5700–5800 cm\(^{−1}\). Quantum yields of ca. 0.75 could be observed for the N,N-dimethylhydrazonyl derivative in nonpolar solvents, which gradually decreased along with increasing solvent polarity, as opposed to the consistently reduced values obtained for the N,N-diphenylhydrazonyl derivative of up to ca. 0.20 in nonpolar solvents. These two push–pull molecules are contrasted with a structurally similar acceptor-π bridge-acceptor (A-π-A) compound.
The interaction of synaptic proteins orchestrate the function of one of the most complex organs, the brain. The multitude of molecular elements influencing neurological correlations makes imaging processes complicated since conventional fluorescence microscopy methods are unable to resolve structures beyond the diffraction-limit.
The implementation of super-resolution fluorescence microscopy into the field of neuroscience allows the visualisation of the fine details of neural connectivity. The key element of my thesis is the super-resolution technique dSTORM (direct Stochastic Optical Reconstruction Microscopy) and its optimisation as a multi-colour approach. Capturing more than one target, I aim to unravel the distribution of synaptic proteins with nanometer precision and set them into a structural and quantitative context with one another. Therefore dSTORM specific protocols are optimized to serve the peculiarities of particular neural samples.
In one project the brain derived neurotrophic factor (BDNF) is investigated in primary, hippocampal neurons. With a precision beyond 15 nm, preand post-synaptic sites can be identified by staining the active zone proteins bassoon and homer. As a result, hallmarks of mature synapses can be exhibited. The single molecule sensitivity of dSTORM enables the measurement of endogenous BDNF and locates BDNF granules aligned with glutamatergic pre-synapses. This data proofs that hippocampal neurons are capable of enriching BDNF within the mature glutamatergic pre-synapse, possibly influencing synaptic plasticity.
The distribution of the metabotropic glutamate receptor mGlu4 is investigated in physiological brain slices enabling the analysis of the receptor in its natural environment. With dual-colour dSTORM, the spatial arrangement of the mGlu4 receptor in the pre-synaptic sites of parallel fibres in the molecular layer of the mouse cerebellum is visualized, as well as a four to six-fold increase in the density of the receptor in the active zone compared to the nearby environment. Prior functional measurements show that metabotropic glutamate receptors influence voltage-gated calcium channels and proteins that are involved in synaptic vesicle priming. Corresponding dSTORM data indeed suggests that a subset of the mGlu4 receptor is correlated with the voltage-gated calcium channel Cav2.1 on distances around 60 nm.
These results are based on the improvement of the direct analysis of localisation data. Tools like coordinated based correlation analysis and nearest neighbour analysis of clusters centroids are used complementary to map protein connections of the synapse. Limits and possible improvements of these tools are discussed to foster the quantitative analysis of single molecule localisation microscopy data.
Performing super-resolution microscopy on complex samples like brain slices benefits from a maximised field of view in combination with the visualisation of more than two targets to set the protein of interest in a cellular context. This challenge served as a motivation to establish a workflow for correlated structured illumination microscopy (SIM) and dSTORM. The development of the visualisation software coSIdSTORM promotes the combination of these powerful super-resolution techniques even on separated setups. As an example, synapses in the cerebellum that are affiliated to the parallel fibres and the dendrites of the Purkinje cells are identified by SIM and the protein bassoon of those pre-synapses is visualised threedimensionally with nanoscopic precision by dSTORM.
In this work I placed emphasis on the improvement of multi-colour super-resolution imaging and its analysing tools to enable the investigation of synaptic proteins. The unravelling of the structural arrangement of investigated proteins supports the building of a synapse model and therefore helps to understand the relation between structure and function in neural transmission processes.
The main objective of this thesis was the design and synthesis of perylene bisimide dyes with sufficient water-solubility for the construction of self-assembled architectures in aqueous solutions. Beside these tasks another goal of this project was the control over the self-assembly process in terms of aggregate size and helicity, respectively. Within this thesis an appropriate synthesis for spermine-functionalized perylene bisimide dyes was developed and conducted successfully. The characterization of these building blocks and their course of self-assembly were investigated by NMR, UV/Vis and fluorescence spectroscopy as well as by atomic force and transmission electron microscopy. For the better understanding of the experimental results theoretical calculations were performed.
Background: The human receptor tyrosine kinase MET and its ligand hepatocyte growth factor/scatter factor are essential during embryonic development and play an important role during cancer metastasis and tissue regeneration. In addition, it was found that MET is also relevant for infectious diseases and is the target of different bacteria, amongst them Listeria monocytogenes that induces bacterial uptake through the surface protein internalin B. Binding of ligand to the MET receptor is proposed to lead to receptor dimerization. However, it is also discussed whether preformed MET dimers exist on the cell membrane.
Results: To address these issues we used single-molecule fluorescence microscopy techniques. Our photobleaching experiments show that MET exists in dimers on the membrane of cells in the absence of ligand and that the proportion of MET dimers increases significantly upon ligand binding.
Conclusions: Our results indicate that partially preformed MET dimers may play a role in ligand binding or MET signaling. The addition of the bacterial ligand internalin B leads to an increase of MET dimers which is in agreement with the model of ligand-induced dimerization of receptor tyrosine kinases.