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Physical regimes characterized by low Mach numbers and steep stratifications pose severe challenges to standard finite volume methods. We present three new methods specifically designed to navigate these challenges by being both low Mach compliant and well-balanced. These properties are crucial for numerical methods to efficiently and accurately compute solutions in the regimes considered.
First, we concentrate on the construction of an approximate Riemann solver within Godunov-type finite volume methods. A new relaxation system gives rise to a two-speed relaxation solver for the Euler equations with gravity. Derived from fundamental mathematical principles, this solver reduces the artificial dissipation in the subsonic regime and preserves hydrostatic equilibria. The solver is particularly stable as it satisfies a discrete entropy inequality, preserves positivity of density and internal energy, and suppresses checkerboard modes.
The second scheme is designed to solve the equations of ideal MHD and combines different approaches. In order to deal with low Mach numbers, it makes use of a low-dissipation version of the HLLD solver and a partially implicit time discretization to relax the CFL time step constraint. A Deviation Well-Balancing method is employed to preserve a priori known magnetohydrostatic equilibria and thereby reduces the magnitude of spatial discretization errors in strongly stratified setups.
The third scheme relies on an IMEX approach based on a splitting of the MHD equations. The slow scale part of the system is discretized by a time-explicit Godunov-type method, whereas the fast scale part is discretized implicitly by central finite differences. Numerical dissipation terms and CFL time step restriction of the method depend solely on the slow waves of the explicit part, making the method particularly suited for subsonic regimes. Deviation Well-Balancing ensures the preservation of a priori known magnetohydrostatic equilibria.
The three schemes are applied to various numerical experiments for the compressible Euler and ideal MHD equations, demonstrating their ability to accurately simulate flows in regimes with low Mach numbers and strong stratification even on coarse grids.
Two-dimensional lattices are in the focus of research in modern solid state physics due to their novel and exotic electronic properties with tremendous potential for seminal future applications. Of particular interest within this research field are quantum spin Hall insulators which are characterized by an insulating bulk with symmetry-protected metallic edge states. For electrons within these one-dimensional conducting channels, spin-momentum locking enables dissipationless transport - a property which promises nothing short of a revolution for electronic devices. So far, however, quantum spin Hall materials require enormous efforts to be realized such as cryogenic temperatures or ultra-high vacuum. A potential candidate to overcome these shortcomings are two-dimensional lattices of the topological semi-metal antimony due to their potential to host the quantum spin Hall effect while offering improved resilience against oxidation.
In this work, two-dimensional lattices of antimony on different substrates, namely Ag(111), InSb(111) and SiC(0001), are investigated regarding their atomic structure and electronic properties with complimentary surface sensitive techniques. In addition, a systematic oxidation study compares the stability of Sb-SiC(0001) with that of the two-dimensional topological insulators bismuthene-SiC(0001) and indenene-SiC(0001).
A comprehensive experimental analysis of the \((\sqrt{3}\times\sqrt{3})R30^\circ\) Sb-Ag(111) surface, including X-ray standing wave measurements, disproves the proclaimed formation of a buckled antimonene lattice in literature. The surface lattice can instead be identified as a metallic Ag\(_2\)Sb surface alloy.
Antimony on InSb(111) shows an unstrained Volmer-Weber island growth due to its large lattice mismatch to the substrate. The concomitant moir\'{e} situation at the interface imprints mainly in a periodic height corrugation of the antimony islands which as observed with scanning tunneling microscopy. On islands with various thicknesses, quasiparticle interference patterns allow to trace the topological surface state of antimony down to the few-layer limit.
On SiC(0001), two different two-dimensional antimony surface reconstructions are identified. Firstly, a metallic triangular $1\times1$ lattice which constitutes the antimony analogue to the topological insulator indenene. Secondly, an insulating asymmetric kagome lattice which represents the very first realized atomic surface kagome lattice.
A comparative, systematic oxidation study of elemental (sub-)monolayer materials on SiC(0001) reveals a high sensitivity of indenene and bismuthene to small dosages of oxygen. An improved resilience is found for Sb-SiC(0001) which, however, oxidizes nevertheless if exposed to oxygen. These surface lattices are therefore not suitable for future applications without additional protective measures.
Vorliegende Untersuchung am Universitätsklinikum Würzburg sowie die Befragung von Anästhesisten/Anästhesistinnen im Raum der 3 DACH-Länder zeigen, dass bildgebende Verfahren bei Säuglingen mit einer niedrigen Rate an Komplikationen, zumeist in medikamentöser Sedierung mit Propofol, durchgeführt werden. Wie international üblich ist im Säuglingsalter die Magnetresonanztomographie das bildgebende Verfahren der Wahl und wird, mit überzeugender Häufigkeit, erfolgreich durchgeführt.
Die Untersuchung am Universitätsklinikum Würzburg legt nahe, dass männliche Säuglinge häufiger eine Bildgebung benötigen und häufiger höheren ASA-Kategorie zugeschrieben werden. Dabei scheinen sie auch häufiger Komplikationen zu erleben und bedürfen daher besonderer Aufmerksamkeit. Eine eventuelle Alternative zur Sedierung kann dabei die „feed-and-sleep“ Methode darstellen. In unserer Umfrage konnten wir erheben, dass diese Methode bisher wenig verbreitet ist, obwohl in diesem Zusammenhang eventuell Abläufe und Prozesszeiten strukturiert und optimiert werden können, da beispielsweise die Nachüberwachung entfällt. Vorstellbar wäre beispielsweise, mehrere Säuglinge zum gleichen Zeitpunkt ins MRT zu bestellen, um gegebenenfalls den am frühesten eingeschlafenen Säugling vorzuziehen. Diese Methode sollte zukünftig Einzug in die wissenschaftliche Untersuchung von bildgebenden Verfahren bei Säuglingen finden.
Die Umfrage im deutschsprachigen Raum zeigt eine Leitlinien-gerechte Betreuung von Säuglingen für bildgebende Verfahren, die mit einer hohen Qualität, und zumeist erfolgreich von erfahrenen Anästhesisten/Anästhesistinnen durchgeführt wird. Eventuelle Verbesserungen können im Bereich der Ausbildung nachfolgender Ärztinnen/Ärzte und in der häufigeren Verwendung der „feed-and-sleep“ Methode liegen, die vielen Kollegen/Kolleginnen bekannt ist, aber nur selten durchgeführt wird.
Ziel ist eine qualitativ hochwertige, schnellstmöglich durchgeführte Bildgebung, die ohne oder mit der niedrigst möglichen Dosierung eines sedierenden Medikamentes zu erreichen ist.
Evaluierung prognostischer und prädiktiver Biomarker beim neoadjuvant vorbehandelten Rektumkarzinom
(2024)
Fragestellung. Osteopontin (OPN) kann im Blut nachgewiesen werden und wird bei vielen Tumorentitäten exprimiert, wie auch der Tyrosinkinaserezeptor c-Met und sein Ligand, das Zytokin Hepatocyte Growth Factor (HGF). In der vorliegenden Arbeit untersuchten wir die prognostische und prädiktive Wertigkeit der Plasmakonzentrationen von OPN, c-Met und HGF bei Patienten mit lokal fortgeschrittenem Rektumkarzinom (LARC).
Methodik. Das Plasma von 63 Patienten mit LARC wurde untersucht. Die Blutentnahmen (EDTA-Plasma) erfolgten vor Therapiebeginn sowie im Verlauf. Die Plasmaspiegel von OPN, c-Met und HGF wurden mittels Enzyme-Linked Immunosorbent Assay analysiert. Die Konzentrationen wurden auf eine Korrelation mit den klinischen Parametern untersucht.
Ergebnisse. 68 Patienten wurden neoadjuvant mit einer Radiochemotherapie behandelt, 63 Blutproben wurden untersucht. Initial befanden sich nach UICC 14 Patienten in Stadium II, 47 in Stadium III und 7 in Stadium IV. Das mediane Follow-Up betrug 29,87 Monate. 20 der 68 Patienten (29,4 %) verstarben, 19 entwickelten Fernmetastasen. OPN korrelierte signifikant mit dem Überleben (p=0,001). OPN-Werte korrelierten mit dem pT-Stadium (R:0,445 p=0,018) und dem pUICC-Stadium (R:0,412 p=0,018), sowie mit dem Auftreten von Fernmetastasen (R:0,271 p=0,031). Eine Korrelation zwischen OPN und dem Therapieansprechen konnte gezeigt werden: pathologisch komplette Remission (pCR) (R:0,379 p=0,001), NAR-Score (R:0,373 p=0,015), TRG (R:0,380 p=0,020). Die logistische Regressionsanalyse ergab eine Prädiktivität OPNs für pCR (OR:0,990 p=0,009), NAR-Score (OR:1,008 p=0,007), TRG (OR:0,459 p=0,008). C-Met und HGF korrelierten nicht mit dem Überleben. Für c-Met und HGF ergab sich keine Korrelation zu initialen klinischen Daten und Therapieansprechen. Die logistische Regression ergab keinen prädiktiven Wert.
Schlussfolgerung. Die Plasmakonzentration von OPN besitzt prognostische und prädiktive Wertigkeit beim LARC. Die Konzentrationen von c-Met und HGF sind nicht prognostisch für das Überleben oder prädiktiv für das Therapieansprechen.
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.
Human prosociality, encompassing generosity, cooperation, and volunteering, holds a vital role in our daily lives. Over the last decades, the question of whether prosociality undergoes changes over the adult lifespan has gained increased research attention. Earlier studies suggested increased prosociality in older compared to younger individuals. However, recent meta-analyses revealed that this age effect might be heterogeneous and modest. Moreover, the contributing factors and mechanisms behind these age-related variations remain to be identified. To unravel age-related differences in prosociality, the first study of this dissertation employed a meta-analytical approach to summarize existing findings and provide insight into their heterogeneity by exploring linear and quadratic age effects on self-reported and behavioral prosociality. Additionally, two empirical research studies investigated whether these age-related differences in prosociality were observed in real life, assessed through ecological momentary assessment (Study 2), and in a controlled laboratory setting by applying a modified dictator game (Study 3). Throughout these three studies, potential underlying behavioral and computational mechanisms were explored. The outcome of the meta-analysis (Study 1) revealed small linear age effects on prosociality and significant age group differences between younger and older adults, with higher levels of prosociality in older adults. Explorative evidence emerged in favor of a quadratic age effect on behavioral prosociality, indicating the highest levels in midlife. Additionally, heightened prosocial behavior among middle-aged adults was observed compared to younger adults, whereas no significant differences in prosocial behavior were noted between middle-aged and older adults. Situational and contextual features, such as the setting of the study and specific paradigm characteristics, moderated the age-prosociality relationship, highlighting the importance of the (social) context when studying prosociality. For Study 2, no significant age effect on real-life prosocial behavior was observed. However, evidence for a significant linear and quadratic age effect on experiencing empathy in real life emerged, indicating a midlife peak. Additionally, across all age groups, the link between an opportunity to empathize and age significantly predicted real-life prosocial behavior. This effect, indicating higher levels of prosocial behavior when there was a situation possibly evoking empathy, was most pronounced in midlife. Study 3 presented age differences in how older and younger adults integrate values related to monetary gains for self and others to make a potential prosocial decision. Younger individuals effectively combined both values in a multiplicative fashion, enhancing decision-making efficiency. Older adults showed an additive effect of values for self and other and displayed increased decision-making efficiency when considering the values separately. However, among older adults, individuals with better inhibitory control were better able to integrate information about both values in their decisions. Taken together, the findings of this dissertation offer new insights into the multi-faceted nature of prosociality across adulthood and the mechanisms that help explain these age-related disparities. While this dissertation observed increasing prosociality across the adult lifespan, it also questions the assumption that older adults are inherently more prosocial. The studies highlight midlife as a potential peak period in social development but also emphasize the importance of the (social) context and that different operationalizations might capture distinct facets of prosociality. This underpins the need for a comprehensive framework to understand age effects of prosociality better and guide potential interventions.
The pancreas is the key organ for the maintenance of euglycemia. This is regulated in particular by α-cell-derived glucagon and β-cell-derived insulin, which are released in response to nutrient deficiency and elevated glucose levels, respectively. Although glucose is the main regulator of insulin secretion, it is significantly enhanced by various potentiators.
Platelets are anucleate cell fragments in the bloodstream that are essential for hemostasis to prevent and stop bleeding events. Besides their classical role, platelets were implemented to be crucial for other physiological and pathophysiological processes, such as cancer progression, immune defense, and angiogenesis. Platelets from diabetic patients often present increased reactivity and basal activation. Interestingly, platelets store and release several substances that have been reported to potentiate insulin secretion by β-cells. For these reasons, the impact of platelets on β-cell functioning was investigated in this thesis.
Here it was shown that both glucose and a β-cell-derived substance/s promote platelet activation and binding to collagen. Additionally, platelet adhesion specifically to the microvasculature of pancreatic islets was revealed, supporting the hypothesis of their influence on glucose homeostasis. Genetic or pharmacological ablation of platelet functioning and platelet depletion consistently resulted in reduced insulin secretion and associated glucose intolerance. Further, the platelet-derived lipid fraction was found to enhance glucose-stimulated insulin secretion, with 20-hydroxyeicosatetraenoic acid (20-HETE) and possibly also lyso-precursor of platelet-activating factor (lysoPAF) being identified as crucial factors. However, the acute platelet-stimulated insulin secretion was found to decline with age, as did the levels of platelet-derived 20-HETE. In addition to their direct stimulatory effect on insulin secretion, specific defects in platelet activation have also been shown to affect glucose homeostasis by potentially influencing islet vascular development. Taking together, the results of this thesis suggest a direct and indirect mechanism of platelets in the regulation of insulin secretion that ensures glucose homeostasis, especially in young individuals.
A highly regulated microenvironment is essential in maintaining normal functioning of the central nervous system (CNS). The existence of a biological barrier, termed as the blood-brain barrier (BBB), at the blood to brain interface effectively allows for selective passage of substances and pathogens into the brain (Kadry, Noorani et al. 2020). The BBB chiefly serves in protecting the brain from extrinsic toxin entry and pathogen invasions. The BBB is formed mainly by brain capillary endothelial cells (BCECs) which are responsible for excluding ∼ 100% of large-molecule neurotherapeutics and more than 98% of all small-molecule drugs from entry into the brain. Minimal BBB transport of major potential CNS drugs allows for attenuated effective treatments for majority of CNS disorders (Appelt-Menzel, Oerter et al. 2020). Animals are generally used as model systems to study neurotherapeutic delivery into the brain, however due to species based disparity, experimental animal models lead to several false positive or false negative drug efficacy predictions thereby being unable to fully predict effects in humans (Ruck, Bittner et al. 2015). An example being that over the last two decades, much of the studies involving animals lead to high failure rates in drug development with ~ 97% failure in cancers and ~ 99% failure for Alzheimer´s disease (Pound 2020). Widespead failures in clinical trials associated with neurological disorders have resulted in questions on whether existing preclinical animal models are genuinely reflective of the human condition (Bhalerao, Sivandzade et al. 2020). Apart from high failure rates in humans, the costs for animal testings is extremely high. According to the Organisation for Economic Co-operation and Development (OECD), responsible for determining animal testing guidelines and methodology for government, industry, and independent laboratories the average cost of a single two-generation reproductive animal toxicity study worldwide is 318,295 € and for Europe alone is ~ 285,842 € (Van Norman 2019). Due to these reasons two separate movements exist within the scientific world, one being to improve animal research and the other to promote new approach methodologies with the European government setting 2025 - 2035 as a deadline for gradually disposing the use of animals in pharmaceutical testing (Pound 2020).
The discovery of human induced pluripotent stem cell (hiPSC) technology in 2006 (Takahashi and Yamanaka 2006, Takahashi, Tanabe et al. 2007) revolutionized the field of drug discovery in-vitro. HiPSCs can be differentiated into various tissue types that mimic disease phenotypes, thereby offering the possibility to deliver humanized in-vitro test systems. With respect to the BBB, several strategies to differentiate hiPSCs to BCECs (iBCECs) are reported over the years (Appelt-Menzel, Oerter et al. 2020). However, iBCECs are said to possess an epithelial or undifferentiated phenotype causing incongruity in BBB lineage specifications (Lippmann,
7
Azarin et al. 2020). Therefore, in order to identify a reliable differentiation strategy in deriving iBCECs possessing hallmark BBB characteristics, which can be used for downstream applications, the work in this thesis compared two methods, namely the co-differentiation (CD) and the directed differentiation (DD). Briefly, CD mimics a brain like niche environment for iBCEC specification (Lippmann, Al-Ahmad et al. 2014), while DD focuses on induction of the mesoderm followed by iBCEC specification (Qian, Maguire et al. 2017). The results obtained verified that while iBCECs derived via CD, in comparison to human BCEC cell line hCMEC/D3 showed the presence of epithelial transcripts such as E-Cadherin (CDH1), and gene level downregulation of endothelial specific platelet endothelial cell adhesion molecule-1 (PECAM-1) and VE-cadherin (CDH5) but demonstrated higher barrier integrity. The CD strategy essentially presented iBCECs with a mean trans-endothelial electrical resistance (TEER) of ~ 2000 – 2500 Ω*cm2 and low permeability coefficients (PC) of < 0.50 μm/min for small molecule transport of sodium fluorescein (NaF) and characteristic BCEC tight junction (TJ) protein expression of claudin-5 and occludin. Additionally, iBCECs derived via CD did not form tubes in response to angiogenic stimuli. DD on the other hand resulted in iBCECs with similar down regulations in PECAM-1 and CDH5 gene expression. They were additionally characterized by lower barrier integrity, measured by mean TEER of only ~ 250 – 450 Ω*cm2 and high PC of > 5 μm/min in small molecule transport of NaF. Although iBCECs derived via DD formed tubes in response to angiogenic stimuli, they did not show positive protein expression of characteristic BCEC TJs such as claudin-5 and occludin. These results led to the hypothesis that maturity and lineage specification of iBCECs could be improved by incorporating in-vivo like characteristics in-vitro, such as direct co-culture with neurovascular unit (NVU) cell types via spheroid formation and by induction of shear stress and fluid flow. In comparison to standard iBCEC transwell mono-cultures, BBB spheroids showed enhanced transcript expression of PECAM-1 and reduced expression of epithelial markers such as CDH1 and claudin-6 (CLDN6). BBB spheroids showed classical BCEC-like ultrastructure that was identified by TJ particles on the protoplasmic face (P-face) and exoplasmic face (E-face) of the plasma membrane. TJ strands were organized as particles and particle-free grooves on the E-face, while on the P-face, partly beaded particles and partly continuous strands were identified. BBB spheroids also showed positive protein expression of claudin-5, VE-cadherin, PECAM-1, glucose transporter-1 (GLUT-1), P-glycoprotein (P-gp) and transferrin receptor-1 (Tfr-1). BBB spheroids demonstrated higher relative impedance percentages in comparison to spheroids without an iBCEC barrier. Barrier integrity assessments additionally corresponded with lower permeability to small molecule tracer NaF, with spheroids containing iBCECs showing higher relative fluorescence unit percentages (RFU%) of ~ 90% in apical compartments, compared to ~ 80% in spheroids without iBCECs. In summary, direct cellular contacts in the complex spheroid model resulted in enhanced maturation of iBCECs.
8
A bioreactor system was used to further assess the effect of shear stress. This system enabled inclusion of fluidic flow and shear stress conditions in addition to non-invasive barrier integrity measurements (Choi, Mathew et al. 2022). iBCECs were cultured for a total of seven days post differentiation (d17) within the bioreactor and barrier integrity was non-invasively monitored. Until d17 of long-term culture, TEER values of iBCECs steadily dropped from ~ 1800 Ω*cm2 ~ 400 Ω*cm2 under static conditions and from ~ 2500 Ω*cm2 to ~ 250 Ω*cm2 under dynamic conditions. Transcriptomic analyses, morphometric analyses and protein marker expression showed enhanced maturation of iBECs under long-term culture and dynamic flow. Importantly, on d10 claudin-5 was expressed mostly in the cytoplasm with only ~ 5% iBCECs showing continuous staining at the cell borders. With increase in culture duration, iBCECs at d17 of static culture showed ~ 18% of cells having continuous cell border expression, while dynamic conditions showed upto ~ 30% of cells with continuous cell-cell border expression patterns. Similarly, ~ 33% of cells showed cell-cell border expression of occludin on d10 with increases to ~ 55% under d17 static and up to ~ 65% under d17 dynamic conditions, thereby indicating iBCEC maturation.
In conclusion, the data presented within this thesis demonstrates the maturation of iBCECs in BBB spheroids, obtained via direct cellular contacts and by the application of flow and shear stress. Both established novel models need to be further validated for pharmaceutical drug applications together with in-vitro-in-vivo correlations in order to exploit their full potential.
Die alveoläre Echinokokkose (AE), die durch den Fuchsbandwurm Echinococcus multilocularis verursacht wird, ist eine seltene jedoch schwere und oft tödlich verlaufende Erkrankung. Aufgrund der späten Diagnosestellung sind kurative Behandlungsmethoden häufig nicht durchführbar und als einzige Behandlungsmöglichkeit bleibt eine lebenslange und nebenwirkungsreiche Therapie mit Benzimidazolen. Verbesserte Therapieoptionen durch die Entwicklung neuer Medikamente sind dringend notwendig. Hierfür kann es hilfreich sein die Biologie des Fuchsbandwurmes und die Kommunikationswege zwischen Parasit und Wirt zu verstehen. Bereits in vorherigen Arbeiten als auch in dieser Arbeit erwiesen sich evolutionsgeschichtlich konservierte Signalwege als Kommunikationsweg zwischen dem Fuchsbandwurm und seinem Wirt von zentraler Rolle.
Die Entschlüsselung des Echinococcus-Genoms gab Hinweise darauf, dass ein Mitglied der Tumornekrosefaktor-Rezeptor-Superfamilie, jedoch kein endogener TNF α ähnlicher Ligand im Genom kodiert wird. Ein Mitglied der TNFR-Superfamilie des Fuchsbandwurmes (EmTNFR) wurde in dieser Arbeit als membranständiger Rezeptor mit einer intrazellulären Todesdomäne (DD) und hoher Ähnlichkeit zum humanen Typ 16 der TNF-Rezeptor-Superfamilie, auch 〖p75〗^NTR genannt, charakterisiert. Sowohl in bioinformatischen als auch in Sequenzanalysen wurden drei alternative Splicing-Formen von emtnfr (emtnfr, emtnfr-v2 und emtnfr-v3) nachgewiesen. emtnfr-v2 entsteht durch Alternatives Splicing und kodiert ein Protein, das keine intrazelluläre Todesdomäne besitzt. emtnfr-v3 verwendet einen alternativen Transkriptionstart und wird von den letzten 3 Exons von emtnfr kodiert. emtnfr-v3, kodiert ein Protein ohne extrazelluläre Region, aber mit intrazellulärer Todesdomäne. Ein löslicher TNF-Rezeptor konnte auf Proteinebene nicht nachgewiesen werden. Aufgrund von phylogenetischen Analysen und der Rezeptor-Struktur ist zu vermuten, dass EmTNFR ein p75NTR Homolog ist und damit der ursprünglichen Form der TNF-Rezeptoren entspricht. Mitglieder eines intrazellulären TNF-Signalweges wurden in bioinformatischen Analysen beim Fuchsbandwurm E. multilocularis identifiziert.
Expressionsuntersuchungen zeigten sowohl in Trankriptomdaten als auch auf Proteinebene eine starke Expression von EmTNFR in Primärzellen und im Metazestoden (MZ), dem pathogenen Stadium für den Zwischenwirt. Echinococcus-Stammzellkulturen zeigten nach RNA-Interferenz-basiertem Knockdown des EmTNFR-kodierenden Gens deutliche Entwicklungsdefekte. Des Weiteren zeigten Echinococcus-Stammzellkulturen nach einer Behandlung mit TNF-α, einem potentiellen Liganden des TNF-Rezeptors und einem zentralen Zytokin in der Immunabwehr des Zwischenwirtes, Entwicklungsfortschritte, wie eine verbesserte Bildung von MZ aus Stammzellen. Zusätzlich wurde in whole-mount in situ Hybridisierungs-Versuchen eine ubiquitäre Expression von emtnfr in der Germinalschicht des MZ sowie eine Spezifität von emtnfr für den MZ, welcher ursächlich für die AE ist, nachgewiesen. Somit scheinen sowohl EmTNFR als auch TNF-α eine wichtige Funktion bei der Entwicklung und Etablierung des Fuchsbandwurmes während der frühen Phase der Infektion des Zwischenwirtes zu haben. TNF-α könnte ein weiterer Faktor für den ausgeprägten Organtropismus des Parasiten zur Leber sein, denn dort bestehen durch Kupfferzellen produzierte hohe lokale Konzentration von TNF-α.
Zusammenfassend deuten die hier erarbeiteten Daten darauf hin, dass EmTNFR über die Bindung von Wirts-TNF-α bei der frühen Entwicklung des Echincoccus-Metazestoden eine Rolle spielt.
The aim of the present work was to improve drug monitoring in patients with various diseases in the context of precision medicine. This was pursued through the development and validation of mass spectrometric methods for determining the drug concentrations of kinase inhibitors and their clinical application. Besides conventional approaches to determine plasma level concentrations, the focus was also on alternative sampling techniques using volumetric absorptive microsampling (VAMS).
A conventional LC-MS/MS method was developed for the determination of cabozantinib in human EDTA plasma and validated according to the guidelines of the European and United States drug authorities (EMA, FDA). The method met the required criteria for linearity, accuracy and precision, selectivity, sensitivity, and stability of the analyte. Validation was also performed for dilution integrity, matrix effect, recovery, and carry-over, with results also in accordance with the requirements. The importance of monitoring the exposure of cabozantinib was demonstrated by a clinical case report of a 34-year-old female patient with advanced adrenocortical carcinoma who also required hemodialysis due to chronic kidney failure. Expected cabozantinib plasma concentrations were simulated for this off-label use based on a population pharmacokinetic model. It was shown that the steady state trough levels were much lower than expected but could not be explained by hemodialysis. Considering the critical condition and potential drug-drug interaction with metyrapone, a substance the patient had taken among several others during the observation period, individual pharmacokinetics could consequently not be estimated without drug monitoring.
In addition, a VAMS method for simultaneous determination of ten kinase inhibitors from capillary blood was developed. This microsampling technique was mainly characterized by the collection of a defined volume of blood, which could be dried and subsequently analyzed. The guidelines for bioanalytical method validation of the EMA and FDA were also used for this evaluation. As the nature of dried blood samples differs from liquid matrices, further parameters were investigated. These include the investigation of the hematocrit effect, process efficiency, and various stability conditions, for example at increased storage temperatures. The validation showed that the developed method is suitable to analyze dried matrix samples accurate, precise, and selective for all analytes. Apart from the stability tests, all acceptance criteria were met. The decreased stability of two analytes was probably due to the reproducible but reduced recovery. In vitro studies provided results on the VAMS-to-plasma correlation to predict the analyte distribution between both matrices, at least in an exploratory manner. It revealed a heterogeneous picture of analytes with different VAMS-to-plasma distributions. Furthermore, the analysis of 24 patient samples indicated the applicability of at-home VAMS. Both should be confirmed later as part of the clinical validation.
The clinical investigation of the VAMS method pursued two objectives. On the one hand, the simultaneous collection of VAMS and serum samples should enable a conversion of the determined concentrations and, on the other hand, the feasibility of autonomous microsampling at home should be examined more closely. For the former, it could be shown that different conversion methods are suitable for converting VAMS concentrations into serum levels. The type of conversion was secondary for the prediction. However, the previously defined criteria could not be fulfilled for all five kinase inhibitors investigated. The framework conditions of the study led to increased variability, especially for analytes with short half-life. A low and varying hematocrit, caused by the underlying disease, also made prediction difficult for a specific patient collective. For the second objective, investigating the feasibility of VAMS, different aspects were considered. It could be shown that the majority of patients support home-based microsampling. The acceptance is likely to increase even further when microsampling is no longer part of a non-interventional study, but participation is accompanied by targeted monitoring and subsequent adjustment of the therapy. The fact that additional training increases understanding of the correct sampling procedure is also a source of confidence. Demonstrated stability during storage under real-life conditions underlines the practicality of this sampling technique.
Taken together, mass spectrometric methods for both plasma and VAMS could be developed and validated, and their clinical application could be successfully demonstrated. The availability of simple bioanalytical methods to determine kinase inhibitor exposure could improve access to prospective studies and thus facilitate the implementation of routine therapeutic drug monitoring.
Site-directed bioorthogonal conjugation techniques have substantially advanced research in numerous areas. Their exceptional value reflects in the extent of applications, that have been realized with spacial-controlled bioorthogonal reactions. Specific labeling of surfaces, proteins, and other biomolecule allows for new generations of drug delivery, tracking, and analyzing systems. With the continuous advance and refinement of available methods, this field of research will become even more relevant in the time to come. Yet, as individual as the desired purpose is, as different can be the most suitable modification strategy. In this thesis, two different bioconjugation approaches, namely CuAAC and factor XIIIa mediated ligation, are used in distinct application fields, featuring eGFP as a model protein showcasing the advantages as well as the challenges of each technique.
The introduction of a unique accessible functionality is the most critical feature of a site-specific reaction, and the first considerable hurdle to clear. While most surfaces, peptides, or small molecules might require less expenditure to modulate, equipping large biomolecules like proteins with additional traits requires careful consideration to preserve the molecule’s stability and function. Therefore, the first section of this project comprises the engineering of eGFP via rational design. Initially, wild-type eGFP was subcloned, expressed, and characterized to serve as a reference value for the designed variants. Subsequently, eGFP was mutated and expressed to display a recognition site for factor XIIIa. Additionally, a second mutant harbored a TAG-codon to enable amber codon suppression and consequently the incorporation of the alkyne bearing unnatural amino acid Plk to support a CuAAC reaction. Fluorescence spectroscopy was used to confirm that the fluorescent properties of all expressed muteins were identically equal to wild-type eGFP, which is a reliable marker for the intact barrel structure of the protein. Trypsin digestion and HPLC were deployed to confirm each protein variant's correct sequence and mass.
The second part of this work focuses on the conjugation of cargo molecules deploying the chosen approaches. Solid-phase peptide synthesis was used to create a peptide that served as a lysine donor substrate in the crosslinking mechanism of FXIIIa. Additionally, the peptide was provided with a cysteine moiety to allow for highly flexible and simple loading of desired cargo molecules via conventional thiol-Michael addition, thus establishing an adaptive labeling platform. The effective ligation was critically reviewed and confirmed by monitoring the exact mass changes by HPLC. Protocols for attaching payloads such as biotin and PEG to the linker peptide were elaborated. While the biotin construct was successfully conjugated to the model protein, the eGFP-PEG linkage was not achieved judging by SDS-PAGE analysis. Furthermore, featuring isolated peptide sequences, the properties of the FXIIIa-mediated reaction were characterized in detail. Relative substrate turnover, saturation concentrations, by-product formation, and incubation time were comprehensively analyzed through HPLC to identify optimal reaction conditions. CuAAC was successfully used to label the Plk-eGFP mutein with Azide-biotin, demonstrated by western blot imaging.
Within the last part of this study, the application of the conjugation systems was extended to different surfaces. As regular surfaces do not allow for immediate decoration, supplementary functionalization techniques like gold-thiol interaction and silanization on metal oxides were deployed. That way gold-segmented nanowires and Janus particles were loaded with enoxaparin and DNA, respectively. Nickel and cobalt nanowires were modified with silanes that served as linker molecules for subsequent small molecule attachment or PEGylation. Finally, the eGFP muteins were bound to a particle surface in a site-specific manner. Beads displaying amino groups were utilized to demonstrate the effective use of FXIIIa in surface modification. Moreover, the bead’s functional moieties were converted to azides to enable CuAAC “Click Chemistry” and direct comparison. Each modification was analyzed and confirmed through fluorescence microscopy.
Die vorliegende Arbeit thematisiert die Aktivität des autonomen Nervensystems im Vergleich vor versus nach bariatrischer Operation bei ProbandInnen mit morbider Adipositas. Wir untersuchten, ob die Operation und der damit einhergehende Gewichtsverlust drei Monate nach dem bariatrischen Eingriff zu einer Veränderung der Aktivität des autonomen Nervensystems im thorakalen und im motorischen/peripheren Kompartiment führt. Als Parameter dienen für das thorakale Kompartiment die Herzfrequenzvariabilität und für das periphere/motorische Kompartiment vaskuläre (lnRHI und AI) und sudomotorische (Schweißvolumen, Antwortlatenz) Parameter.
Unsere Ergebnisse im thorakalen Kompartiment zeigen einen Anstieg der Herzfrequenzvariabilität 3 Monate nach bariatrischer Operation. Wir schließen uns daher der Hypothese an, die mit morbider Adipositas assoziierte Erhöhung der sympathischen Aktivität im thorakalen Kompartiment könne durch bariatrische Operationen reversibel sein. Im peripheren/motorischen Kompartiment können wir keine eindeutige Veränderung der Aktivität des autonomen Nervensystems vor versus nach bariatrischer Operation beobachten. Andere Studien konnten hierzu deutlichere Ergebnisse erheben, die ebenfalls eine erhöhte sympathische Aktivität im motorischen Kompartiment zeigten, welche nach bariatrischer Operation reversibel war.
Insgesamt können wir die These einer autonomen Imbalance bei Adipositas sowie einer Verringerung der sympathischen Aktivität im thorakalen Kompartiment nach bariatrischer Operation unterstützen. Die Veränderungen im autonomen Nervensystem leisten möglicherweise einen Beitrag zur Verbesserung der kardiovaskulären Gesundheit und der metabolischen Situation nach der bariatrischen Operation.
Charcot-Marie-Tooth (CMT) Neuropathien stellen als häufigste erblich bedingte neurologische Erkrankungen eine Gruppe genetisch heterogener, chronisch progredienter peripherer Polyneuropathien dar. Die Lebensqualität der Patienten ist bei fehlender kurativer Therapieoption vor allem durch motorische und sensorische Defizite deutlich eingeschränkt. In verschiedenen Studien konnte die pathophysiologische Relevanz einer sekundären Entzündungsreaktion, insbesondere durch Makrophagen und Lymphozyten vermittelt, in Mausmodellen dreier CMT1 Subtypen (CMT1A, CMT1B, CMT1X) aufgezeigt werden. Auch in Folge einer Läsion peripherer Nerven ist eine akute Entzündungsreaktion von entscheidender Bedeutung, wobei sich bereits Gemeinsamkeiten zwischen der postläsionalen Waller´schen Degeneration (WD) und CMT1 Neuropathien identifizieren ließen. Während die aktive Beteiligung der Autophagie Schwann´scher Zellen (hier kurz SZ Autophagie genannt) an der Myelindegradation im Falle einer WD jedoch vielfach beschrieben wurde, ist Ähnliches in CMT1 Neuropathien bisher nur unzureichend untersucht. Da in einer Studie in Cx32def Mausmodellen der CMT1X Erkrankung auch nach Reduktion endoneuraler Makrophagen anhaltende Demyelinisierung beobachtet werden konnte, sollte das Vorkommen von SZ Autophagie sowie deren mögliche Beeinflussung durch Makrophagen in diesen Myelinmutanten untersucht werden.
In der vorliegenden Arbeit wurden sowohl Wildtyp (Wt) Mäuse in ex vivo und in vivo Modellen einer WD als auch Cx32def Myelinmutanten zweier Altersstufen (4 und 12 Monate) mit einem niedermolekularen CSF1-Rezeptor-Inhibitor (CSF1RI) zur Reduktion endoneuraler Makrophagen behandelt, wobei sich vergleichende histochemische bzw. immunhistochemische Analysen peripherer Nerven behandelter und unbehandelter Tiere anschlossen.
Im Rahmen der Etablierung immunhistochemischer Methodik zeigte sich hierbei unter den kontrollierten Bedingungen einer ex vivo Ischiasnervenkultur eine vermehrte Aktivierung der SZ Autophagie in behandelten Wt Mäusen. Auch 4 Monate alte behandelte Cx32def Tiere wiesen, verglichen mit unbehandelten Myelinmutanten bzw. Wt Mäusen derselben Altersstufe, eine vermehrte autophagische Aktivität in SZ auf. Diese scheint sich jedoch im weiteren Verlauf der Erkrankung zu reduzieren, da im Falle der 12 Monate alten Cx32def Modelltiere weniger autophagisch aktive SZ Profile bzw. kaum Unterschiede zwischen behandelten und unbehandelten Tieren beobachtet werden konnten.
Die Ergebnisse lassen somit eine mögliche aktive Beteiligung von SZ Autophagie insbesondere in der Pathophysiologie der frühen Phase einer CMT1X Erkrankung sowie deren Beeinflussung durch endoneurale Makrophagen vermuten. Dies sollte vornehmlich in der Entwicklung von Therapiestrategien der CMT1X bedacht werden, da sich eine frühe Reduktion pathophysiologisch relevanter endoneuraler Makrophagen somit auch nachteilig auf die Myelinintegrität auswirken könnte.
In dieser Arbeit wurde der Einfluss sozialer Stresserfahrung sowie des 5-Htt-Genotyps auf die neuronale Morphologie bestimmter Hirnregionen anhand eines Mausmodells untersucht. Es wurde in mit Golgi-Cox gefärbten Gehirnen der 5-HTT-KO-Linie in der lateralen Amygdala (LA) die Apikal- und Basaldendriten pyramidenzellähnlicher Neurone und die Apikaldendriten der Pyramidenzellen der Cornu ammonis (CA)3-Region des Hippocampus mithilfe des Neurolucidasystems rekonstruiert und die so gewonnenen Daten anschließend statistisch ausgewertet.
Die erzielten Ergebnisse belegen, dass vor allem die Erfahrung von sozialem Verteidigungsstress aber auch der 5-Htt-Genotyp (WT, HET, KO) im Mausmodell signifikanten Einfluss auf die Morphologie der Neurone der LA und der CA3-Region besitzen. Um die in dieser Arbeit mit allen drei 5-Htt-Genotypen erzielten Ergebnisse der LA-Neurone besser mit den Ergebnissen von Nietzer und Bonn (nur WT, KO) vergleichen zu können (Nietzer et al., 2011), wurden die von mir erhobenen Daten nicht nur in einem 3er-Vergleich, sondern auch einem 2er-Vergleich (WT vs. KO) statistisch analysiert. Untersuchungen der LA-Neurone aller drei 5-Htt-Genotypen zeigen, dass sozialer Stress zu einer Zunahme der Komplexität der Dendritenbäume durch längere und auch stärker verzweigte Dendriten vor allem in der Gruppe der WT-Mäuse führt. HET- und KO-Mäuse zeigten keinen entsprechenden Stress-Effekt. Darüber hinaus zeigten sich deutliche Genotypeffekte. Unabhängig vom Stresserleben besitzen HET-Mäuse längere Dendriten als WT-Mäuse sowie eine höhere Spinedichte als WT- und KO-Mäuse. Die Hypothese, die in der Arbeit von Nietzer et al. aufgestellt wurde, dass eine vollständige 5-HTT-Defizienz zu mehr Spines führt, ließ sich hier weder durch den 3er- noch durch den 2er-Vergleich replizieren. Die Pyramidenzellen der CA3-Region, die in dieser Studie zum ersten Mal analysiert wurden, zeigen in Bezug auf die durch den Stress ausgelösten Veränderungen ein im Vergleich zu den LA-Neuronen entgegengesetzten Effekt. Der soziale Stress führt hier zu einer Dendritenatrophie in der WT-Gruppe mit kürzeren und weniger komplexen Dendriten. Außerdem führte er zu einer geringeren Spinedichte bei den HET-Mäusen. Es zeigten sich klare Genotypeffekte, unabhängig von der Stresserfahrung, mit einer reduzierten Spinedichte der KO-Mäuse gegenüber den WT-Mäusen und einer nur in den Kontrollen detektierten, reduzierten Spinedichte der KO-Mäuse im Vergleich zu den WT- und HET-Mäusen. Sowohl in der LA als auch in der CA3-Region lassen sich Kompensationsmechanismen des 5-HTT-Defizits der HET-Tiere vermuten, über die die KO-Tiere nicht verfügen.
Die in LA und CA3 gezeigten gegensätzlichen Auswirkungen des sozialen Stresses weisen auf die unterschiedlichen Funktionen dieser beiden Regionen im Furchtkreislauf und/oder bei der Verarbeitung von Stress hin. Darüber hinaus deutet diese Arbeit darauf hin, dass Arbeiten mit ähnlichen Untersuchungsmethoden und sogar gleichem Untersuchungsmaterial unterschiedliche Ergebnisse liefern können.
Bei Großschadensereignissen oder Katastrophen arbeiten die Einsatzkräfte verschiedener Organisationen und Krankenhäuser zusammen, um die Schadenslage zu bewältigen. Für die Koordinierung dieser Einsätze benötigen die Führungskräfte ein möglichst genaues Bild der aktuellen Lage. Auch im Rahmen der SARS-CoV-2- Pandemie war eine Übersicht über die Versorgungslage der Krankenhäuser erforderlich, um mögliche lokale Ressourcenengpässe frühzeitig zu erkennen und durch geeignete Maßnahmen zu beheben. Zu diesem Zweck wurde in Bayern im November 2021 das Windmühlen-Modell eingeführt. Basierend auf einer Online-Plattform meldeten die zuständigen Bezirkskoordinierenden der bayerischen Regierungsbezirke täglich die Versorgungslage ihrer Kliniken anhand der Komponenten Personal, Material und Raum. Außerdem gab es die Möglichkeit zur Dokumentation von Patientenverlegungen. Die über die Windmühlen-Onlineplattform gesammelten Lagemeldungen und dokumentierten Verlegungen des Zeitraums von 21. November 2021 bis 20. Februar 2022 wurden in der vorliegenden Arbeit detailliert aufbereitet. Zusätzlich wurden die erfassten Daten statistisch ausgewertet und mit den örtlichen 7-Tage-Inzidenzwerten des SARS-CoV-2-Virus verglichen. Durch das Windmühlen-Modell konnten Unterschiede in der Versorgungslage zwischen den Regierungsbezirken sehr effektiv sichtbar gemacht werden. Insgesamt waren Intensivstationen deutlich stärker belastet als Normalstationen. Die Versorgungsqualität war in Covid-Bereichen stärker beeinträchtigt als auf Stationen ohne Covid-Patienten. Es konnte nachgewiesen werden, dass die Windmühlen-Lagemeldungen nicht allein die regionalen Inzidenzwerte, sondern die tatsächliche Versorgungssituation vor Ort abbilden. Die dokumentierten Interhospitaltransfers erfolgten von Regionen mit hohen Inzidenzwerten und schlechter Ressourcenverfügbarkeit in Bezirke mit weniger kritischer Versorgungslage. Damit konnten aus den Windmühlen-Lagemeldungen auch konkrete Handlungskonsequenzen, wie strategische Patientenverlegungen, abgeleitet werden. Lagemeldungen sind wichtig für die abgestimmte Zusammenarbeit verschiedener Stellen bei der Bewältigung einer Krise. Die etablierten Systeme zur Lageerfassung sind meist quantitativ ausgelegt und nur wenig skalierbar. Die Anwendung in einem neuen Kontext erfordert oft zeitaufwändige Anpassungen. Im Gegensatz dazu bietet das Windmühlen-Modell eine skalierbare, eher qualitativ ausgerichtete Lagedarstellung und ist aufgrund seines unkomplizierten Aufbaus innerhalb kürzester Zeit für eine Nutzung in verschiedensten Schadenslagen adaptierbar.
Ubiquitination is an important post-translational modification that maintains cellular homeostasis by regulating various biological processes. Deubiquitinases (DUBs) are enzymes that reverse the ubiquitination process by catalyzing the removal of ubiquitin from a substrate. Abnormal expression or function of DUBs is often associated with the onset and progression of various diseases, including cancer. Ubiquitin specific proteases (USPs), which constitute the largest family of DUBs in humans, have become the center of interest as potential targets in cancer therapy as many of them display increased activity or are overexpressed in a range of malignant tumors or the tumor microenvironment.
Two related members of the USP family, USP28 and USP25, share high sequence identities but play diverse biological roles. USP28 regulates cell proliferation, oncogenesis, DNA damage repair and apoptosis, whereas USP25 is involved in the anti-viral response, innate immunity and ER-associated degradation in addition to carcinogenesis. USP28 and USP25 also exhibit different oligomeric states – while USP28 is a constitutively active dimer, USP25 assumes an auto-inhibited tetrameric structure. The catalytic domains of both USP28 and USP25 comprise the canonical, globular USP-domain but contain an additional, extended insertion site called USP25/28 catalytic domain inserted domain (UCID) that mediates oligomerization of the proteins. Disruption of the USP25 tetramer leads to the formation of an activated dimeric protein. However, it is still not clear what triggers its activation.
Due to their role in maintaining and stabilizing numerous oncoproteins, USP28 and USP25 have emerged as interesting candidates for anti-cancer therapy. Recent advances in small-molecular inhibitor development have led to the discovery of relatively potent inhibitors of USP28 and USP25. This thesis focuses on the structural elucidation of USP28 and the biochemical characterization of USP28/USP25, both in complex with representatives of three out of the eight compound classes reported as USP28/USP25-specific inhibitors. The crystal structures of USP28 in complex with the AZ compounds, Vismodegib and FT206 reveal that all three inhibitor classes bind into the same allosteric pocket distant from the catalytic center, located between the palm and the thumb subdomains (the S1-site). Intriguingly, this binding pocket is identical to the UCID-tip binding interface in the USP25 tetramer, rendering the protein in a locked, inactive conformation. Formation of the binding pocket in USP28 requires a shift in the helix α5, which induces conformational changes and local distortion of the binding channel that typically accommodates the C-terminal tail of Ubiquitin, thus preventing catalysis and abrogating USP28 activity. The key residues of the USP28-inhibitor binding pocket are highly conserved in USP25. Mutagenesis studies of these residues accompanied by biochemical and biophysical assays confirm the proposed mechanism of inhibition and similar binding to USP25.
This work provides valuable insights into the inhibition mechanism of the small molecule compounds specifically for the DUBs USP28 and USP25. The USP28-inhibitor complex structures offer a framework to develop more specific and potent inhibitors.
Sprech- und Stimmstörungen sind häufige Symptome der Idiopathischen Parkinson Erkrankung (IPS), wobei bis zu 89% der Patienten im Verlauf der Krankheit unter einer Dysarthrie leiden. Die Tiefenhirnstimulation des Nucleus subthalamicus (STN-DBS) ist eine etablierte Behandlung für die motorischen Symptome des IPS (Allert et al., 2004). Während STN-DBS positive Effekte auf einige Teilfunktionsbereiche der Dysarthrie zu haben scheint, berichten die meisten Studien entweder über keine Verbesserung oder eine Verschlechterung der Sprech- und Stimmfunktionen nach Implantation der STN-DBS (Tsuboi et al., 2015; Wang et al., 2003; Wertheimer et al., 2014). Klinische Erfahrungswerte sowie Fallberichte und Studien lassen vermuten, dass diese sprachtherapeutisch relevanten Nebenwirkungen unabhängig von der therapeutischen Wirksamkeit der STN-DBS sind und daher als unerwünschte, aber nicht therapieimmanente Interferenzfaktoren anzusehen sind (Bouthour et al., 2018), die es genauer zu untersuchen gilt, da die Lebensqualität von IPS-Erkrankten als stark einschränkend wahrgenommen wird (Hariz et al., 2010). Eine aufwendige und methodisch fundierte Klassifizierung wurde von Tsuboi und Kollegen vorgenommen, die im Zusammenhang mit STN-DBS fünf Cluster von Sprech- und Stimmstörungen identifizierten (Tanaka et al., 2020; Tsuboi et al., 2015, 2017). Dazu zählten die Phänotypen „spastische Dysarthrie“, „Stottern“, „rigid-hypokinetischer Typ“, „behauchte Stimme“ und „gepresste Stimme“.
Erste Hinweise lassen darauf schließen, dass die Nebenwirkungen von STN-DBS auf die Stimulation spezifischer Gehirnkreise zurückzuführen sein könnte (Fox et al., 2014). In dieser Arbeit wird eine retrospektive Studie mit STN-DBS stimulierten IPS Erkrankten vorgestellt, die sprachtherapeutisch relevante Sprech- und Stimmstörungen unter zwei Bedingungen bewertet (ein- und ausgeschaltete Stimulation) sowie eine prospektive Studie mit den beiden gleichen Bedingungen. Beide Studien haben das Ziel einer Replizierbarkeit der Ergebnisse von Tsuboi et al. (2015, 2017). Die zweite prospektive Studie bezieht außerdem konnektombasierte Daten ein.
Die Ergebnisse beider Studien lassen quantitativ keine Signifikanzen hinsichtlich der o.g. dysarthrischen Phänotypen zu, quantitativ lassen sich jedoch deutliche Tendenzen ähnlich der Ausgangsstudie erkennen. Zudem wurden das Cluster „Stottern“ in der retrospektiven Studie als weiteres möglicherweise STN-DBS immantentes Cluster identifiziert. In der prospektiven Studie wurde ein Cluster hinzugefügt, da in den Beurteilungen zusätzlich die Symptomatik „hasty speech“ oder auch „hastiges Sprechen“ beobachtet wurde.
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.
Colorectal Cancer (CRC) is the third most common cancer in the US. The majority of CRC cases are due to deregulated WNT-signalling pathway. These alterations are mainly caused by mutations in the tumour suppressor gene APC or in CTNNB1, encoding the key effector protein of this pathway, β-Catenin. In canonical WNT-signalling, β-Catenin activates the transcription of several target genes, encoding for proteins involved in proliferation, such as MYC, JUN and NOTCH. Being such a critical regulator of these proto-oncogenes, the stability of β-Catenin is tightly regulated by the Ubiquitin-Proteasome System. Several E3 ligases that ubiquitylate and degrade β-Catenin have been described in the past, but the antagonists, the deubiquitylases, are still unknown. By performing an unbiased siRNA screen, the deubiquitylase USP10 was identified as a de novo positive regulator of β-Catenin stability in CRC derived cells. USP10 has previously been shown in the literature to regulate both mutant and wild type TP53 stability, to deubiquitylate NOTCH1 in endothelial cells and to be involved in the regulation of AMPKα signalling. Overall, however, its role in colorectal tumorigenesis remains controversial. By analysing publicly available protein and gene expression data from colorectal cancer patients, we have shown that USP10 is strongly upregulated or amplified upon transformation and that its expression correlates positively with CTNNB1 expression. In contrast, basal USP10 levels were found in non-transformed tissues, but surprisingly USP10 is upregulated in intestinal stem cells. Endogenous interaction studies in CRC-derived cell lines, with different extend of APCtruncation, revealed an APC-dependent mode of action for both proteins. Furthermore, by utilising CRISPR/Cas9, shRNA-mediated knock-down and overexpression of USP10, we could demonstrate a regulation of β-Catenin stability by USP10 in CRC cell lines. It is widely excepted that 2D cell culture systems do not reflect complexity, architecture and heterogeneity and are therefore not suitable to answer complex biological questions. To overcome this, we established the isolation, cultivation and genetically modification of murine intestinal organoids and utilised this system to study Usp10s role ex vivo. By performing RNA sequencing, dependent on different Usp10 levels, we were able to recapitulate the previous findings and demonstrated Usp10 as important regulator of β-dependent regulation of stem cell homeostasis. Since genetic depletion of USP10 resulted in down-regulation of β-Catenin-dependent transcription, therapeutic intervention of USP10 in colorectal cancer was also investigated. Commercial and newly developed inhibitors were tested for their efficacy against USP10, but failed to significantly inhibit USP10 activity in colorectal cancer cells. To validate the findings from this work also in vivo, development of a novel mouse model for colorectal cancer has begun. By combining CRISPR/Cas9 and classical genetic engineering with viral injection strategies, WT and genetically modified mice could be transformed and, at least in some animals, intestinal lesions were detectable at the microscopic level. The inhibition of USP10, which we could describe as a de novo tumour-specific regulator of β-Catenin, could become a new therapeutic strategy for colorectal cancer patients.
This dissertation explores the development and assessment of inhibitory control – a crucial component of executive functions – in young children. Inhibitory control, defined as the ability to suppress inappropriate responses (Verbruggen & Logan, 2008), is essential for adaptable and goal-oriented behavior. The rapid and non-linear development of this cognitive function in early childhood presents unique challenges for accurate assessment. As children age, they often exhibit a ceiling effect in terms of response accuracy (Petersen et al., 2016), underscoring the need to consider response latency as well. Ideally, combining response latency with accuracy could yield a more precise measure of inhibitory control (e.g., Magnus et al., 2019), facilitating a detailed tracking of developmental changes in inhibitory control across a wider age spectrum. The three studies of this dissertation collectively aim to clarify the relationship between response accuracy, response latency, and inhibitory control across different stages of child development. Each study utilizes a computerized Pointing Stroop Task (Berger et al., 2000) to measure inhibitory control, examining the task's validity and the integration of dual metrics for a more comprehensive evaluation.
The first study focuses on establishing the validity of using both response accuracy and latency as indicators of inhibitory control. Utilizing the framework of explanatory item-response modeling (De Boeck & Wilson, 2004), the study revealed how the task characteristics congruency and item position influence both the difficulty level and timing aspects in young children’s responses in the computerized Pointing Stroop task. Further, this study found that integrating response accuracy with latency, even in a basic manner, provides additional insights. Building upon these findings, the second study investigates the nuances of integrating response accuracy and latency, examining whether this approach can account for age-related differences in inhibitory control. It also explores whether response latencies may contain different information depending on the age and proficiency of the children. The study leverages novel and established methodological perspectives to integrate response accuracy and latency into a single metric, showing the potential applicability of different approaches for assessing inhibitory control development. The third study extends the investigation to a longitudinal perspective, exploring the dynamic relationship between response accuracy, latency, and inhibitory control over time. It assesses whether children who achieve high accuracy at an earlier age show faster improvement in response latency, suggesting a non-linear maturation pathway of inhibitory control. The study also examines if the predictive value of early response latency for later fluid intelligence is dependent on the response accuracy level.
Together, these empirical studies contribute to a more robust understanding of the complex interaction between inhibitory control, response accuracy, and response latency, facilitating valid evaluations of cognitive capabilities in children. Moreover, the findings may have practical implications for designing educational strategies and clinical interventions that address the developmental trajectory of inhibitory control. The nuanced approach advocated in this dissertation suggests prioritizing accuracy in assessment and interventions during the early stages of children's cognitive development, gradually shifting the focus to response latency as children mature and secure their inhibitory control abilities.