@phdthesis{Kurz2020, author = {Kurz, Andreas}, title = {Correlative live and fixed cell superresolution microscopy}, doi = {10.25972/OPUS-19945}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199455}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {Over the last decade life sciences have made an enormous leap forward. The development of complex analytical instruments, in particular in fluorescence microscopy, has played a decisive role in this. Scientist can now rely on a wide range of imaging techniques that offer different advantages in terms of optical resolution, recording speed or living cell compatibility. With the help of these modern microscopy techniques, multi-protein complexes can be resolved, membrane receptors can be counted, cellular pathways analysed or the internalisation of receptors can be tracked. However, there is currently no universal technique for comprehensive experiment execution that includes dynamic process capture and super resolution imaging on the same target object. In this work, I built a microscope that combines two complementary imaging techniques and enables correlative experiments in living and fixed cells. With an image scanning based laser spot confocal microscope, fast dynamics in several colors with low photodamage of the cells can be recorded. This novel system also has an improved resolution of 170 nm and was thoroughly characterized in this work. The complementary technique is based on single molecule localization microscopy, which can achieve a structural resolution down to 20-30 nm. Furthermore I implemented a microfluidic pump that allows direct interaction with the sample placed on the microscope. Numerous processes such as living cell staining, living cell fixation, immunostaining and buffer exchange can be observed and performed directly on the same cell. Thus, dynamic processes of a cell can be frozen and the structures of interest can be stained and analysed with high-resolution microscopy. Furthermore, I have equipped the detection path of the single molecule technique with an adaptive optical element. With the help of a deformable mirror, imaging functions can be shaped and information on the 3D position of the individual molecules can be extracted.}, subject = {Einzelmolek{\"u}lmikroskopie}, language = {en} } @phdthesis{Hagmann2020, author = {Hagmann, Hanns Antony}, title = {The impact of the CRISPR/Cas system on the interaction of Neisseria meningitidis with human host cells}, doi = {10.25972/OPUS-19949}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199490}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {Neisseria meningitidis, a commensal β-proteobacterium residing exclusively in the human nasopharynx, is a leading cause of sepsis and epidemic meningitis worldwide. While comparative genome analysis was able to define hyperinvasive lineages that are responsible for most of the cases of invasive meningococcal disease (IMD), the genetic basis of their virulence remains unclear. Recent studies demonstrate that the type II C CRISPR/Cas system of meningococci is associated with carriage and less invasive lineages. CRISPR/Cas, an adaptive defence system against foreign DNA, was shown to be involved in gene regulation in Francisella novicida. This study shows that knockout strains of N. meningitidis lacking the Cas9 protein are impaired in the adhesion to human nasopharyngeal cells in a strain-dependant manner, which constitutes a central step in the pathogenesis of IMD. Consequently, this study indicates that the meningococcal CRISPR/Cas system fulfils functions beyond the defence of foreign DNA and is involved in the regulation of meningococcal virulence.}, subject = {CRISPR/Cas-Methode}, language = {en} } @phdthesis{Zhu2020, author = {Zhu, Mo}, title = {Germination and differentiation of \(Blumeria\) \(graminis\) ascospores and effects of UV-C and white light irradiation on \(B.\) \(graminis\) conidial prepenetration}, doi = {10.25972/OPUS-16647}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-166470}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {Blumeria graminis, the obligate biotrophic grass powdery mildew, is a highly pathogenic fungus capable of inflicting foliar diseases and of causing severe yield losses. There is asexual and sexual propagation in the life cycle of B. graminis. In the epidemiological processes of this pathogen, both types of spores - asexual conidia and sexual ascospores - are crucial. Conidia of B. graminis are demonstrated to perceive cuticular very-long-chain aldehydes as molecular signal substances notably promoting germination and differentiation of the infection structure (the appressorium) - the prepenetration processes - in a concentration- and chain-length-dependent manner. Conidial germination and appressorium formation are known to be dramatically impeded by the presence of free water on the host surface. However, sexually formed ascospores are reported to easily germinate immersed in water. There are abundant assays on conidial prepenetration processes. However, with respect to the stimulating effects of very-long-chain aldehydes and to the influence of the presence of free water, ascosporic prepenetration processes are still obscure. In order to study the effects of very-long-chain aldehydes on the ascosporic prepenetration processes of wheat powdery mildew fungus B. graminis f. sp. tritici, Formvar®-based in vitro systems were applied to exclude the secondary host effects (such as host resistance) and to reproducibly provide homogeneous hydrophobic substratum surfaces. By the presence of even-numbered very-long-chain aldehydes (C22 - C30), the appressorium formation of the ascospores was notably triggered in a chain-length dependent manner. N-octacosanal (C28) was the most inducing aldehyde tested. Unlike conidia, ascospores could easily differentiate immersed in water and showed a more variable differentiation pattern even with a single germ tube differentiating an appressorium. To evaluate the alternative management against barley powdery mildew fungus Blumeria graminis f. sp. hordei, the suppressing effects of UV-C irradiation on the developmental processes of conidia on artificial surfaces (in vitro) and on host leaf surfaces (in vivo) were assayed. In vitro and in vivo, a single dose of 100 J m-2 UV-C was adequate to decrease conidial germination to < 20 \% and to reduce appressorium formation to values < 5 \%. UV-C irradiation negatively affected colony pustule size and vegetative propagation. Under photoperiodic conditions of 2h light/16h dark, 6h dark/12h light or 6h dark/18h light, UV-C-treated conidia showed photoreactivation (photo-recovery). White light-mediated photoreactivation was most effective immediately after UV-C irradiation, suggesting that a prolonged phase of darkness after UV-C application increased the efficacy of management against B. graminis. UV-C irradiation increased transcript levels of three putative photolyase genes in B. graminis, indicating those were probably involved in photoreactivation processes. However, mere white light or blue light (wavelength peak, 475 nm) could not induce the up-regulation of these genes. To determine whether visible light directly impacted the prepenetration and penetration processes of this powdery mildew pathogen, conidia of Blumeria graminis f. sp. hordei and Blumeria graminis f. sp. tritici were inoculated onto artificial surfaces and on host leaf surfaces. Samples were analyzed after incubation periods under light conditions (white light intensity and spectral quality). Increasing white light intensities directly impaired conidial prepenetration processes in vitro but not in vivo. Applying an agar layer under the wax membrane compensated for conidial water loss as a consequence of high white light irradiation. Light stimulated in vitro and in vivo the appressorium elongation of B. graminis in a wavelength-dependent manner. Red light was more effective to trigger the elongation of appressorium than blue light or green light assayed. Taken together, the findings of this study demonstrate that 1) a host surface recognition principle based on cuticular very-long-chain aldehydes is a common feature of B. graminis f. sp. tritici ascospores and conidia; 2) the transcriptional changes of three putative photolyase genes in B. graminis are mediated in a UV-C-dependent manner; 3) light directly affected the (pre)penetration processes of B. graminis.}, subject = {Blumeria graminis}, language = {en} }