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Sonstige beteiligte Institutionen
- Fraunhofer-Institut für Silicatforschung ISC (8)
- Helmholtz Institute for RNA-based Infection Research (HIRI) (7)
- Universitätsklinikum Würzburg (5)
- Fraunhofer Institut für Silicatforschung ISC (3)
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- D-3057-2014 (1)
- I-5818-2014 (1)
- J-8841-2015 (1)
- M-1240-2017 (1)
- N-2030-2015 (1)
- N-3741-2015 (1)
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Die Arbeit befasst sich mit der Akademisierung und Professionalisierung der Zahnheilkunde, insbesondere der Zahnchirurgie, in Würzburg und Unterfranken im 19. Jahrhundert. Dies wurde insbesondere anhand des zahnchirurgischen Teils der Lehrchirurgischen Instrumentensammlung der Universität Würzburg bzw. des Juliusspitals erforscht. Der zahnchirurgische Teil der Instrumentensammlung war bisher noch nicht erforscht worden und besteht aktuell aus 34+1 Instrumenten, die für diese Arbeit komplett katalogisiert wurden. Für die Entwicklung der Instrumente im Verlauf des 19. Jahrhunderts wurde die Provenienz der Teilsammlung ergründet und diese in den Kontext der Akademisierungsbewegung des 19. Jahrhunderts eingeordnet.
Die Forschung wurde anhand der tatsächlich in der Praxis tätigen und nach und nach akademisch ausgebildeten Personen nachvollzogen. Hierzu wurden neben den Instrumenten als Quelle die Adressbücher der Stadt Würzburg und die Matrikel-, Personal- und Vorlesungsverzeichnisse der Universität Würzburg des gesamten 19. Jahrhunderts systematisch durchgearbeitet. Außerdem wurden Lehrbücher aus dem nichtakademischen zahnchirurigischen Bereich (Bader) mit denen aus dem sich beginnenden akademischen Bereich analysiert. Anhand dieser Forschungsarbeit konnte dargelegt werden, dass die Zahnchirurgie sich analog zur Chiurgie aus dem handwerklichen Bereich abgekoppelt und nach und nach auf verschiedenen Stufen akademisiert hat. Die Zahnchirurgie hat sich "von unten nach oben" durch das Bestreben nichtakademisch ausgebildeter Menschen akademisiert.
Colon carcinomas (CRC) are statistically among the most fatal cancer types and hence one of the top reasons for premature mortality in the developed world. CRC cells are characterized by high proliferation rates caused by deregulation of gene transcription of proto-oncogenes and general chromosomal instability. On macroscopic level, CRC cells show a strongly altered nutrient and energy metabolism.
This work presents research to understand general links between the metabolism and transcription alteration. Mainly focussing on glutamine dependency, shown in colon carcinoma cells and expression pathways of the pro-proliferation protein c-MYC.
Previous studies showed that a depletion of glutamine in the cultivation medium of colon carcinoma cell lines caused a proliferation arrest and a strong decrease of overall c-MYC levels. Re-addition of glutamine quickly replenished c-MYC levels through an unknown mechanism. Several proteins altering this regulation mechanism were identified and proposed as possible starting point for further in detail studies to unveil the precise biochemical pathway controlling c-MYC translation repression and reactivation in a rapid manner.
On a transcriptional level the formation of RNA:DNA hybrids, so called R-loops, was observed under glutamine depleted conditions. The introduction and overexpression of RNaseH1, a R-loop degrading enzyme, in combination with an ectopically expressed c-MYC variant, independent of cellular regulation mechanisms by deleting the regulatory 3’-UTR of the c-MYC gene, lead to a high rate of apoptotic cells in culture. Expression of a functionally inactive variant of RNaseH1 abolished this effect. This indicates a regulatory function of R-loops formed during glutamine starvation in the presence of c-MYC protein in a cell. Degradation of R-loops and high c-MYC levels in this stress condition had no imminent effect on the cell cycle progression is CRC cells but disturbed the nucleotide metabolism. Nucleotide triphosphates were strongly reduced in comparison to starving cells without R-loop degradation and proliferating cells.
This study proposes a model of a terminal cycle of transcription termination, unregulated initiation and elongation of transcription leading to a depletion of energy resources of cells. This could finally lead to high apoptosis of the cells. Sequencing experiments to determine a coinciding of termination sites and R-loop formation sides failed so far but show a starting point for further studies in this essential survival mechanism involving R-loop formation and c-MYC downregulation.
Over the years, hydrogels have been developed and used for a huge variety of different applications ranging from drug delivery devices to medical products. In this thesis, a poly(2-methyl-2-oxazoline) (POx) / poly(2-n-propyl-2-oxazine) (POzi) bioink was modified and analyzed for the use in biofabrication and targeted drug delivery. In addition, the protein fibrinogen (Fbg) was genetically modified for an increased stability towards plasmin degradation for its use as wound sealant.
In Chapter 1, a thermogelling, printable POx/POzi-based hydrogel was modified with furan and maleimide moieties in the hydrophilic polymer backbone facilitating post-printing maturation of the constructs via Diels-Alder chemistry. The modification enabled long-term stability of the hydrogel scaffolds in aqueous solutions which is necessary for applications in biofabrication or tissue engineering. Furthermore, we incorporated RGD-peptides into the hydrogel which led to cell adhesion and elongated morphology of fibroblast cells seeded on top of the scaffolds. Additional printing experiments demonstrate that the presented POx/POzi system is a promising platform for the use as a bioink in biofabrication.
Chapter 2 highlights the versatility of the POx/POzi hydrogels by adapting the system to a use in targeted drug delivery. We used a bioinspired approach for a bioorthogonal conjugation of insulin-like growth factor I (IGF-I) to the polymer using an omega-chain-end dibenzocyclooctyne (DBCO) modification and a matrix metalloprotease-sensitive peptide linker. This approach enabled a bioresponsive release of IGF-I from hydrogels as well as spatial control over the protein distribution in 3D printed constructs which makes the system a candidate for the use in personalized medicine.
Chapter 3 gives a general overview over the necessity of wound sealants and the current generations of fibrin sealants on the market including advantages and challenges. Furthermore, it highlights trends and potential new strategies to tackle current problems and broadens the toolbox for future generations of fibrin sealants.
Chapter 4 applies the concepts of recombinant protein expression and molecular engineering to a novel generation of fibrin sealants. In a proof-of-concept study, we developed a new recombinant fibrinogen (rFbg) expression protocol and a Fbg mutant that is less susceptible to plasmin degradation. Targeted lysine of plasmin cleavage sites in Fbg were exchanged with alanine or histidine in different parts of the molecule. The protein was recombinantly produced and restricted plasmin digest was analyzed using high resolution mass spectrometry. In addition to that, we developed a novel time resolved screening protocol for the detection of new potential plasmin cleavage sites for further amino acid exchanges in the fibrin sealant.
Kovalente Inhibition stellt einen effektiven Weg dar, die Verweildauer des Liganden innerhalb einer Bindetasche zu erhöhen. In dieser Arbeit wurden theoretische Methoden angewendet, um die Reaktivität und den nichtkovalenten Zustand vor der Reaktion zu modellieren. Im Rahmen einer Fallstudie zu Cathepsin K wurden nichtkovalente Modelle von kovalenten Inhibitoren generiert. Für verschiedene Komplexe aus Cathepsin K und einem kovalent gebundenem Liganden wurde der Zustand vor der Reaktion modelliert und dessen Stabilität im Rahmen einer klassischen MD-Simulation überprüft. Die Stabilität des Warheads in der Bindetasche hing hauptsächlich vom gewählten Protonierungszustand der katalytischen Aminosäuren ab. Für eine Reihe von Inhibitoren der ChlaDUB1 wurde ein Protokoll aus quantenmechanischen Rechnungen genutzt, um die Reaktivität verschiedener Warheads abzuschätzen. Die erhaltenen Aktivierungsenergien korrelierten mit experimentell bestimmten Raten zur Inaktivierung des Enzyms. Im Rahmen eines Wirkstoffdesign-Projektes zur Deubiquitinase USP28 wurden von unpublizierten Kristallstrukturen ausgehend erste Docking-Experimente durchgeführt. Es konnte gezeigt werden, dass ein literaturbekannter Inhibitor von USP28 mit einem Warhead so modifiziert werden kann, dass die reaktive Einheit in direkter Nachbarschaft zu einem Cystein positioniert wird. Für diese Warheads wurden ebenfalls quantenmechanische Rechnungen zur Bestimmung der Aktivierungsenergie durchgeführt. Um besser nachvollziehen zu können, warum bei einem Photoswitch-Inhibitor der Butyrylcholin-Esterase der cis-Zustand des Moleküls besser inhibiert als der trans-Zustand, wurde eine Docking-Studie des Zustandes vor der Reaktion durchgeführt. Es konnte ein qualitatives Modell aufgestellt werden, das zeigt, dass der trans-Zustand aufgrund seiner längeren Form mit wichtigen Aminosäuren am Eingang der Bindungstasche kollidiert.
This thesis investigates the charged moments and the symmetry-resolved
entanglement entropy in the context of the AdS3/CFT2 duality. In the
first part, I focus on the holographic U(1) Chern-Simons-Einstein gravity,
a toy model of AdS3/CFT2 with U(1) Kac-Moody symmetry. I
start with the vacuum background with a single entangling interval. I
show that, apart from a partition function in the grand canonical ensemble,
the charged moments can also be interpreted as the two-point
function of vertex operators on the replica surface. For the holographic
description, I propose a duality between the bulk U(1) Wilson line and
the boundary vertex operators. I verify this duality by deriving the
effective action for the Chern-Simons fields and comparing the result
with the vertex correlator. In the twist field approach, I show that the
charged moments are given by the correlation function of the charged
twist operators and the additional background operators. To solve the
correlation functions involved, I prove the factorization of the U(1) extended
conformal block into a U(1) block and a Virasoro block. The
general expression for the U(1) block is derived by directly summing
over the current descendant states, and the result shows that it takes
an identical form as the vertex correlators. This leads to the conclusion
that the disjoint Wilson lines compute the neutral U(1) block. The final
result for the symmetry-resolved entanglement entropy shows that
it is always charge-independent in this model. In the second part, I
study charged moments in higher spin holography, where the boundary
theory is a CFT with W3 symmetry. I define the notion of the
higher spin charged moments by introducing a spin-3 modular charge
operator. Restricting to the vacuum background with a single entangling
interval, I employ the grand canonical ensemble interpretation
and calculate the charged moments via the known higher spin black
hole solution. On the CFT side, I perform a perturbative expansion for
the higher spin charged moments in terms of the connected correlation
functions of the spin-3 modular charge operators. Using the recursion
relation for the correlation functions of the W3 currents, I evaluate the
charged moments up to the quartic order of the chemical potential. The
final expression matches with the holographic result. My results both
for U(1) Chern-Simons Einstein gravity and W3 higher spin gravity
constitute novel checks of the AdS3/CFT2 correspondence.
Interactions between host and pathogen determine the development, progression and outcomes
of disease. Medicine benefits from better descriptions of these interactions through increased
precision of prevention, diagnosis and treatment of diseases. Single-cell genomics is a
disruptive technology revolutionizing science by increasing the resolution with which we study
diseases. Cell type specific changes in abundance or gene expression are now routinely investigated
in diseases. Meanwhile, detecting cellular phenotypes across diseases can connect
scientific fields and fuel discovery. Insights acquired through systematic analysis of high resolution
data will soon be translated into clinical practice and improve decision making. Therefore,
the continued use of single-cell technologies and their application towards clinical samples will
improve molecular interpretation, patient stratification, and the prediction of outcomes.
In the past years, I was fortunate to participate in interdisciplinary research groups bridging
biology, clinical research and data science. I was able to contribute to diverse projects through
computational analysis and biological interpretation of sequencing data. Together, we were
able to discover cellular phenotypes that influence disease progression and outcomes as well
as the response to treatment. Here, I will present four studies that I have conducted in my PhD.
First, we performed a case study of relapse from cell-based immunotherapy in Multiple Myeloma.
We identified genomic deletion of the epitope as mechanism of immune escape and implicate
heterozygosity or monosomy of the genomic locus at baseline as a potential risk factor. Second,
we investigated the pathomechanisms of severe COVID-19 at the earliest stage of the COVID-
19 pandemic in Germany in March 2020. We discovered that profibrotic macrophages and
lung fibrosis can be caused by SARS-CoV-2 infection. Third, we used a mouse model of chronic
infection with Staphylococcus aureus that causes Osteomyelitis similar to the human disease.
We were able to identify dysregulated immunometabolism associated with the generation of
myeloid-derived suppressor cells (MDSC). Fourth, we investigated Salmonella infection of the
human small intestine in an in vitro model and describe features of pathogen invasion and host
response.
Overall, I have been able to successfully employ single-cell sequencing to discover important
aspects of diseases ranging from development to treatment and outcome. I analyzed samples
from the clinics, human donors, mouse models and organoid models to investigate different
aspects of diseases and managed to integrate data across sample types, technologies and
diseases. Based on successful studies, we increased our efforts to combine data from multiple
sources to build comprehensive references for the integration of large collections of clinical
samples. Our findings exemplify how single-cell sequencing can improve clinical research and
highlights the potential of mechanistic discoveries to drive precision medicine.
Die distale Radiusfraktur gehört zu den häufigsten Frakturen in Deutschland mit einem Inzidenzanstieg im Alter unter Betonung des weiblichen Geschlechts. Dabei zeigt sich ein zunehmender Trend in Richtung operative Versorgung, allen voran die Versorgung mittels winkelstabiler Plattensysteme. Instabile, distale Radiusfrakturen werden dabei vor geplanter operativer Versorgung im Rahmen der Initialbehandlung üblicherweise geschlossen reponiert und im Gipsverband retiniert. Ziel der vorliegenden monozentrischen, prospektiv randomisierten Studie mit zwei Studiengruppen war es herauszufinden, ob sich das Unterlassen der Reposition vor geplanter Operation nachteilig auf das Schmerzniveau in der präoperativen Phase auswirkt und ob sich durch die Dislokation Nachteile in Bezug auf den Nervus medianus im Sinne eines Traktionsschadens sowie bezüglich des klinisch-radiologischen Ausheilungsergebnisses zeigen.
Die Studie zeigte, dass das Schmerzempfinden während der präoperativen Gipsbehandlung unabhängig von einer vorherigen Reposition war. Für den primären Endpunkt an Tag 1 nach der Akutbehandlung konnte statistisch signifikante Nichtunterlegenheit der Gruppe ohne Reposition gegenüber der Gruppe mit Reposition nachgewiesen werden. Gleiches galt für Tag 2, sowohl für die absoluten Schmerzniveaus als auch für die Schmerzlinderung.
Das Unterlassen der Reposition hatte zudem keine nachteiligen Effekte auf den Nervus medianus.
Gleiches zeigte sich für das klinische und radiologische Ausheilungsergebnis. Für die funktionellen DASH- und Krimmer-Scores konnte ein Jahr postoperativ ebenfalls statistisch signifikante Nichtunterlegenheit der Gruppe ohne Reposition nachgewiesen werden.
Diese Erkenntnisse bestätigen die in der Literatur vorhandenen Ergebnisse verschiedener Studien dahingehend, dass das Unterlassen der Reposition keine nachteiligen Effekte auf das postoperative Outcome hat. Einige Studien verdeutlichen zudem, dass es nach Reposition, insbesondere bei Vorliegen gewisser Risiko- und Instabilitätsfaktoren, ohnehin zur sekundären Dislokation kommt, sodass die generelle Notwendigkeit der Reposition vor Gipsanlage sowohl vor einer operativen als auch vor einer konservativen Weiterbehandlung angezweifelt werden
muss.
African trypanosomes are unicellular parasites that cause nagana and sleeping sickness in livestock and man, respectively. The major pathogens for the animal disease include Trypanosoma vivax, T. congolense, and T. brucei brucei, whereas T. b. gambiense and T. b. rhodesiense are responsible for human infections. Given that the bloodstream form (BSF) of African trypanosomes is exclusively extracellular, its cell surface forms a critical boundary with the host environment. The cell surface of the BSF African trypanosomes is covered by a dense coat of immunogenic variant surface glycoproteins (VSGs). This surface protein acts as an impenetrable shield that protects the cells from host immune factors and is also involved in antibody clearance and antigenic variation, which collectively ensure that the parasite stays ahead of the host immune system. Gene expression in T. brucei is markedly different from other eukaryotes: most genes are transcribed as long polycistronic units, processed by trans-splicing a 39-nucleotide mini exon at the 5′ and polyadenylation at the 3′ ends of individual genes to generate the mature mRNA.
Therefore, gene expression in T. brucei is regulated post-transcriptionally, mainly by the action of RNA binding proteins (RBPs) and conserved elements in the 3′ untranslated regions (UTR) of transcripts. The expression of VSGs is highly regulated, and only a single VSG gene is expressed at a time from one of the ~15 subtelomeric domains termed bloodstream expression sites (BES). When cells are engineered to simultaneously express two VSGs, the total VSG mRNA do not exceed the wild type amounts. This suggests that a robust VSG mRNA balancing mechanism exists in T. brucei. The present study uses inducible and constitutive expression of ectopic VSG genes to show that the endogenous VSG mRNA is regulated only if the second VSG is properly targeted to the ER. Additionally, the endogenous VSG mRNA response is triggered when high amounts of the GFP reporter with a VSG 3′UTR is targeted to the ER. Further evidence that non-VSG ER import signals can efficiently target VSGs to the ER is presented. This study suggests that a robust trans-regulation of the VSG mRNA is elicited at the ER through a feedback loop to keep the VSG transcripts in check and avoid overshooting the secretory pathway capacity.
Further, it was shown that induction of expression of the T. vivax VSG ILDat1.2 in T. brucei causes a dual cell cycle arrest, with concomitant upregulation of the protein associated with differentiation (PAD1) expression. It could be shown that T. vivax VSG ILDat1.2 can only be sufficiently expressed in T. brucei after replacing its native GPI signal peptide with that of a T. brucei VSG. Taken together, these data indicate that inefficient VSG GPI anchoring and expression of low levels of the VSG protein can trigger differentiation from slender BSF to stumpy forms. However, a second T. vivax VSG, ILDat2.1, is not expressed in T. brucei even after similar modifications to its GPI signals. An X-ray crystallography approach was utilized to solve the N-terminal domain (NTD) structure of VSG ILDat1.2. This is first structure of a non-T. brucei VSG, and the first of a surface protein of T. vivax to be solved. VSG ILDat1.2 NTD maintains the three-helical bundle scaffold conserved in T. brucei surface proteins. However, it is likely that there are variations in the architecture of the membrane proximal region of the ILDat1.2 NTD and its CTD from T. brucei VSGs. The tractable T. brucei system is presented as a model that can be used to study surface proteins of related trypanosome species, thus creating avenues for further characterization of trypanosome surface coats.
Die von Friedhelm Brusniak und Ulrich Konrad betreute und angenommene Dissertation nimmt den Briefwechsel zwischen August Heinrich Hoffmann von Fallersleben und dem jüngeren Augsburger Kapellmeister und Komponisten Hans Michael Schletterer in den Jahren 1862 bis 1873 in den Blick und dokumentiert dabei Hoffmanns Einfluss auf den Entstehungsprozess der Vertonungen seiner Lieder, besonders seiner Kinderlieder. Die Arbeit beleuchtet zudem den Erfahrungsschatz, den sich der ‚Dichter-Sänger‘ Hoffmann von Fallersleben auch durch die Zusammenarbeit mit anderen Musikern seiner Zeit, vorrangig Ludwig Christian Erk (1807–1883) und Ernst Heinrich Leopold Richter (1805–1876), erworben hatte. Darüber hinaus werden in der Korrespondenz Themen des gesellschaftlichen und politischen Lebens, der privaten und beruflichen Situation beider wie auch Hoffmanns Rolle als väterlicher Berater Schletterers berührt. Die Arbeit darf als neuer substantieller Beitrag der Hoffmann-Forschung und der interdisziplinären Liedforschung angesehen werden, der insbesondere der Kinderliedforschung neue Impulse verleiht.
Among the defense strategies developed in microbes over millions of years, the innate adaptive CRISPR-Cas immune systems have spread across most of bacteria and archaea. The flexibility, simplicity, and specificity of CRISPR-Cas systems have laid the foundation for CRISPR-based genetic tools. Yet, the efficient administration of CRISPR-based tools demands rational designs to maximize the on-target efficiency and off-target specificity. Specifically, the selection of guide RNAs (gRNAs), which play a crucial role in the target recognition of CRISPR-Cas systems, is non-trivial. Despite the fact that the emerging machine learning techniques provide a solution to aid in gRNA design with prediction algorithms, design rules for many CRISPR-Cas systems are ill-defined, hindering their broader applications.
CRISPR interference (CRISPRi), an alternative gene silencing technique using a catalytically dead Cas protein to interfere with transcription, is a leading technique in bacteria for functional interrogation, pathway manipulation, and genome-wide screens. Although the application is promising, it also is hindered by under-investigated design rules. Therefore, in this work, I develop a state-of-art predictive machine learning model for guide silencing efficiency in bacteria leveraging the advantages of feature engineering, data integration, interpretable AI, and automated machine learning. I first systematically investigate the influential factors that attribute to the extent of depletion in multiple CRISPRi genome-wide essentiality screens in Escherichia coli and demonstrate the surprising dominant contribution of gene-specific effects, such as gene expression level. These observations allowed me to segregate the confounding gene-specific effects using a mixed-effect random forest (MERF) model to provide a better estimate of guide efficiency, together with the improvement led by integrating multiple screens. The MERF model outperformed existing tools in an independent high-throughput saturating screen. I next interpret the predictive model to extract the design rules for robust gene silencing, such as the preference for cytosine and disfavoring for guanine and thymine within and around the protospacer adjacent motif (PAM) sequence. I further incorporated the MERF model in a web-based tool that is freely accessible at www.ciao.helmholtz-hiri.de.
When comparing the MERF model with existing tools, the performance of the alternative gRNA design tool optimized for CRISPRi in eukaryotes when applied to bacteria was far from satisfying, questioning the robustness of prediction algorithms across organisms. In addition, the CRISPR-Cas systems exhibit diverse mechanisms albeit with some similarities. The captured predictive patterns from one dataset thereby are at risk of poor generalization when applied across organisms and CRISPR-Cas techniques. To fill the gap, the machine learning approach I present here for CRISPRi could serve as a blueprint for the effective development of prediction algorithms for specific organisms or CRISPR-Cas systems of interest. The explicit workflow includes three principle steps: 1) accommodating the feature set for the CRISPR-Cas system or technique; 2) optimizing a machine learning model using automated machine learning; 3) explaining the model using interpretable AI. To illustrate the applicability of the workflow and diversity of results when applied across different bacteria and CRISPR-Cas systems, I have applied this workflow to analyze three distinct CRISPR-Cas genome-wide screens. From the CRISPR base editor essentiality screen in E. coli, I have determined the PAM preference and sequence context in the editing window for efficient editing, such as A at the 2nd position of PAM, A/TT/TG downstream of PAM, and TC at the 4th to 5th position of gRNAs. From the CRISPR-Cas13a screen in E. coli, in addition to the strong correlation with the guide depletion, the target expression level is the strongest predictor in the model, supporting it as a main determinant of the activation of Cas13-induced immunity and better characterizing the CRISPR-Cas13 system. From the CRISPR-Cas12a screen in Klebsiella pneumoniae, I have extracted the design rules for robust antimicrobial activity across K. pneumoniae strains and provided a predictive algorithm for gRNA design, facilitating CRISPR-Cas12a as an alternative technique to tackle antibiotic resistance.
Overall, this thesis presents an accurate prediction algorithm for CRISPRi guide efficiency in bacteria, providing insights into the determinants of efficient silencing and guide designs. The systematic exploration has led to a robust machine learning approach for effective model development in other bacteria and CRISPR-Cas systems. Applying the approach in the analysis of independent CRISPR-Cas screens not only sheds light on the design rules but also the mechanisms of the CRISPR-Cas systems. Together, I demonstrate that applied machine learning paves the way to a deeper understanding and a broader application of CRISPR-Cas systems.