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Formation of specialized pro-resolving lipid mediators (SPMs) such as lipoxins or resolvins usually involves arachidonic acid 5-lipoxygenase (5-LO, ALOX5) and different types of arachidonic acid 12- and 15-lipoxygenating paralogues (15-LO1, ALOX15; 15-LO2, ALOX15B; 12-LO, ALOX12). Typically, SPMs are thought to be formed via consecutive steps of oxidation of polyenoic fatty acids such as arachidonic acid, eicosapentaenoic acid or docosahexaenoic acid. One hallmark of SPM formation is that reported levels of these lipid mediators are much lower than typical pro-inflammatory mediators including the monohydroxylated fatty acid derivatives (e.g., 5-HETE), leukotrienes or certain cyclooxygenase-derived prostaglandins. Thus, reliable detection and quantification of these metabolites is challenging. This paper is aimed at critically evaluating i) the proposed biosynthetic pathways of SPM formation, ii) the current knowledge on SPM receptors and their signaling cascades and iii) the analytical methods used to quantify these pro-resolving mediators in the context of their instability and their low concentrations. Based on current literature it can be concluded that i) there is at most, a low biosynthetic capacity for SPMs in human leukocytes. ii) The identity and the signaling of the proposed G-protein-coupled SPM receptors have not been supported by studies in knock-out mice and remain to be validated. iii) In humans, SPM levels were neither related to dietary supplementation with their ω-3 polyunsaturated fatty acid precursors nor were they formed during the resolution phase of an evoked inflammatory response. iv) The reported low SPM levels cannot be reliably quantified by means of the most commonly reported methodology. Overall, these questions regarding formation, signaling and occurrence of SPMs challenge their role as endogenous mediators of the resolution of inflammation.
Rhizomes from Zingiber officinale Roscoe are traditionally used for the treatment of a plethora of pathophysiological conditions such as diarrhea, nausea, or rheumatoid arthritis. While 6-gingerol is the pungent principle in fresh ginger, in dried rhizomes, 6-gingerol is dehydrated to 6-shogaol. 6-Shogaol has been demonstrated to exhibit anticancer, antioxidative, and anti-inflammatory actions more effectively than 6-gingerol due to the presence of an electrophilic Michael acceptor moiety. In vitro, 6-shogaol exhibits anti-inflammatory actions in a variety of cell types, including leukocytes. Our study focused on the effects of 6-shogaol on activated endothelial cells. We found that 6-shogaol significantly reduced the adhesion of leukocytes onto lipopolysaccharide (LPS)-activated human umbilical vein endothelial cells (HUVECs), resulting in a significantly reduced transmigration of THP-1 cells through an endothelial cell monolayer. Analyzing the mediators of endothelial cell–leukocyte interactions, we found that 30 µM of 6-shogaol blocked the LPS-triggered mRNA and protein expression of cell adhesion molecules. In concert with this, our study demonstrates that the LPS-induced nuclear factor κB (NFκB) promoter activity was significantly reduced upon treatment with 6-shogaol. Interestingly, the nuclear translocation of p65 was slightly decreased, and protein levels of the LPS receptor Toll-like receptor 4 remained unimpaired. Analyzing the impact of 6-shogaol on angiogenesis-related cell functions in vitro, we found that 6-shogaol attenuated the proliferation as well as the directed and undirected migration of HUVECs. Of note, 6-shogaol also strongly reduced the chemotactic migration of endothelial cells in the direction of a serum gradient. Moreover, 30 µM of 6-shogaol blocked the formation of vascular endothelial growth factor (VEGF)-induced endothelial sprouts from HUVEC spheroids and from murine aortic rings. Importantly, this study shows for the first time that 6-shogaol exhibits a vascular-disruptive impact on angiogenic sprouts from murine aortae. Our study demonstrates that the main bioactive ingredient in dried ginger, 6-shogaol, exhibits beneficial characteristics as an inhibitor of inflammation- and angiogenesis-related processes in vascular endothelial cells.
Catecholaminergic polymorphic ventricular tachycardia (CPVT) is an inherited disturbance of the heart rhythm (arrhythmia) that is induced by stress or that occurs during exercise. Most mutations that have been linked to CPVT are found in two genes, i.e., ryanodine receptor 2 (RyR2) and calsequestrin 2 (CASQ2), two proteins fundamentally involved in the regulation of intracellular Ca2+ in cardiac myocytes. We inserted six CPVT-causing mutations via clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9 into unc-68 and csq-1, the Caenorhabditis elegans homologs of RyR and CASQ, respectively. We characterized those mutations via video-microscopy, electrophysiology, and calcium imaging in our previously established optogenetic arrhythmia model. In this study, we additionally enabled high(er) throughput recordings of intact animals by combining optogenetic stimulation with a microfluidic chip system. Whereas only minor/no pump deficiency of the pharynx was observed at baseline, three mutations of UNC-68 (S2378L, P2460S, Q4623R; RyR2-S2246L, -P2328S, -Q4201R) reduced the ability of the organ to follow 4 Hz optogenetic stimulation. One mutation (Q4623R) was accompanied by a strong reduction of maximal pump rate. In addition, S2378L and Q4623R evoked an altered calcium handling during optogenetic stimulation. The 1,4-benzothiazepine S107, which is suggested to stabilize RyR2 channels by enhancing the binding of calstabin2, reversed the reduction of pumping ability in a mutation-specific fashion. However, this depends on the presence of FKB-2, a C. elegans calstabin2 homolog, indicating the involvement of calstabin2 in the disease-causing mechanisms of the respective mutations. In conclusion, we showed for three CPVT-like mutations in C. elegans RyR a reduced pumping ability upon light stimulation, i.e., an arrhythmia-like phenotype, that can be reversed in two cases by the benzothiazepine S107 and that depends on stabilization via FKB-2. The genetically amenable nematode in combination with optogenetics and high(er) throughput recordings is a promising straightforward system for the investigation of RyR mutations and the selection of mutation-specific drugs.
The scope of this thesis is to elaborate on the use cases of the EEG in pain research. It has been submitted as a cumulative dissertation, meaning that the main part of this thesis has been previously published in international peer-reviewed journals. The first part of this thesis begins with an introduction which describes the general methodoligcal considerations and theoretical background information that is needed to perform pain research using the EEG. Then, I will give a summary of the results of all three studies and the subsequently published manuscripts. The discussion will give an outlook on two ongoing projects and elaborate how the methodology that has been compiled throughout my time as a PhD student can be further applied to scientific problems in pain research. I will conclude with the possibilities and the limitations of the EEG in pain research. The second part of this thesis consists of three publications that cover three individual studies, of which I am the lead/first author. These publications describe different use cases for the EEG in pain research. The first publication lays out the methodological backbone of this thesis, analyzing the exact EEG parameters that are needed to achieve the results in the following projects. Then, I present two additional studies. The first study describes the usefulness of pain-related evoked signatures after standardized noxious stimulation in the EEG in patients undergoing general anesthesia. The second study outlines differences in the pain processing of elite endurance athletes versus a normally active control group. Furthermore, it outlines how the function of the endogenous pain modulatory system can be measured in the EEG using CPM. All studys are discussed individually as per the journal guidelines.
K+ plays an essential role in a different cellular processes in bacteria, and is a central player in microbial adaptation towards a number of environmental challenges. Accordingly, K+ transporters are subject to tight regulation by a diverse set of mechanisms. Here, we discuss three regulatory strategies from three transport systems, as well as the general regulation of K+ homeostasis by the second messenger c-di-AMP.
Background. Recent pathomolecular studies on the MLL-AF4 fusion protein revealed that the murinized version of MLL-AF4, the MLL-Af4 fusion protein, was able to induce leukemia when expressed in murine or human hematopoietic stem/progenitor cells (Lin et al. in Cancer Cell 30:737–749, 2016). In parallel, a group from Japan demonstrated that the pSer domain of the AF4 protein, as well as the pSer domain of the MLL-AF4 fusion is able to bind the Pol I transcription factor complex SL1 (Okuda et al. in Nat Commun 6:8869, 2015). Here, we investigated the human MLL-AF4 and a pSer-murinized version thereof for their functional properties in mammalian cells. Gene expression profiling studies were complemented by intracellular localization studies and functional experiments concerning their biological activities in the nucleolus.
Results: Based on our results, we have to conclude that MLL-AF4 is predominantly localizing inside the nucleolus, thereby interfering with Pol I transcription and ribosome biogenesis. The murinized pSer-variant is localizing more to the nucleus, which may suggest a different biological behavior. Of note, AF4-MLL seems to cooperate at the molecular level with MLL-AF4 to steer target gene transcription, but not with the pSer-murinized version of it.
Conclusion: This study provides new insights and a molecular explanation for the described differences between hMLL-hAF4 (not leukemogenic) and hMLL-mAf4 (leukemogenic). While the human pSer domain is able to efficiently recruit the SL1 transcription factor complex, the murine counterpart seems to be not. This has several consequences for our understanding of t(4;11) leukemia which is the most frequent leukemia in infants, childhood and adults suffering from MLL-r acute leukemia.
In Vorarbeiten wurde gezeigt, dass der Kaliumkanal Slack an der Verarbeitung neuropathischer Schmerzen funktionell beteiligt ist und dass das klassische Neuroleptikum Loxapin Slack-abhängig neuropathisches Schmerzverhalten im Mausmodell lindert (Lu et al. 2015).
Ausgehend von Loxapin als Leitstruktur wurden in der vorliegenden Arbeit im FluxOR™ Kaliumkanal-Assay an Slack-transfizierten HEK-Zellen insgesamt 68 neue Loxapin-Derivate gescreent. Hierbei wurden 23 Substanzen mit Slack-aktivierenden Eigenschaften identifiziert, von denen VHP93, VH408 und VH425 weiter in vivo untersucht wurden. Dabei zeigten Mäuse nach systemischer Gabe von VHP93 ein reduziertes Verhalten in einem Modell für neuropathische Schmerzen. Dem gegenüber wurde durch VH408 das Verhalten im neuropathischen Schmerzmodell nicht beeinflusst.
Des Weiteren konnte in dieser Arbeit gezeigt werden, dass durch eine Slack-Aktivierung nicht nur neuropathisches Schmerzverhalten gehemmt wird, sondern auch die Kratzreaktionen im Chloroquin-Modell des Histamin-unabhängigen Juckreizes reduziert werden können.
Neben Slack wurde in dieser Arbeit auch die Gewebsexpression und funktionelle Bedeutung des eng mit Slack verwandten Kaliumkanals Slick charakterisiert. Expressionsanalysen ergaben, dass Slick überwiegend in dünn myelinisierten A-delta-Fasern und inhibitorischen Interneuronen im Dorsalhorn des Rückenmarks lokalisiert ist. Tierexperimentelle Untersuchungen zeigten, dass Slick-Knockout-Mäuse ein erhöhtes Schmerzverhalten nach thermischer Stimulation aufwiesen. Außerdem wurde bei Slick-Knockout-Mäusen in der späten Phase des Capsaicin- und Formalin-Tests ein signifikant erhöhtes Leckverhalten verzeichnet. Die Ergebnisse dieser Arbeit liefern somit Hinweise auf eine funktionelle Beteiligung von Slick bei der Detektion von Hitzeschmerzen und bei der TRPV1- und TRPA1-vermittelten Schmerzantwort. Zusammengefasst zeigen diese Daten, dass Slick vorrangig an der Verarbeitung thermischer und chemischer Noxen beteiligt ist und dabei eine antinozizeptive Funktion ausübt.
The repertoire of natural products offers tremendous opportunities for chemical biology and drug discovery. Natural product-inspired synthetic molecules represent an ecologically and economically sustainable alternative to the direct utilization of natural products. De novo design with machine intelligence bridges the gap between the worlds of bioactive natural products and synthetic molecules. On employing the compound Marinopyrrole A from marine Streptomyces as a design template, the algorithm constructs innovative small molecules that can be synthesized in three steps, following the computationally suggested synthesis route. Computational activity prediction reveals cyclooxygenase (COX) as a putative target of both Marinopyrrole A and the de novo designs. The molecular designs are experimentally confirmed as selective COX-1 inhibitors with nanomolar potency. X-ray structure analysis reveals the binding of the most selective compound to COX-1. This molecular design approach provides a blueprint for natural product-inspired hit and lead identification for drug discovery with machine intelligence.
Mitochondrial NADH:ubiquinone oxidoreductase (complex I) is a 1-MDa membrane protein complex with a central role in energy metabolism. Redox-driven proton translocation by complex I contributes substantially to the proton motive force that drives ATP synthase. Several structures of complex I from bacteria and mitochondria have been determined, but its catalytic mechanism has remained controversial. We here present the cryo-EM structure of complex I from Yarrowia lipolytica at 2.1-Å resolution, which reveals the positions of more than 1600 protein-bound water molecules, of which ~100 are located in putative proton translocation pathways. Another structure of the same complex under steady-state activity conditions at 3.4-Å resolution indicates conformational transitions that we associate with proton injection into the central hydrophilic axis. By combining high-resolution structural data with site-directed mutagenesis and large-scale molecular dynamic simulations, we define details of the proton translocation pathways and offer insights into the redox-coupled proton pumping mechanism of complex I.
Lysosomes are major degradative organelles that contain enzymes capable of breaking down proteins, nucleic acids, carbohydrates, and lipids. In the last decade, new discoveries have traced also important roles for lysosomes as signalling hubs, affecting metabolism, autophagy and pathogenic infections. Therefore, maintenance of a healthy lysosome population is of utmost importance to the cell to respond to both stress conditions and also homeostatic signalling. For example, for minor perturbations to the lysosomal membrane, the cell activates repair processes which seal membrane nicks. For more extensive damage, autophagy is activated to remove damaged organelles from the cell. on the other hand, during pathogen invasion host cells have also evolved mechanisms to hijack the endolysosomal pathway to facilitate their own growth and replication in host cells.
The first part of the thesis work focuses on a lysosomal regeneration program which is activated under conditions where the entire lysosomal pool of the cell is damaged. Upon extensive membrane damage induced by the lysosomotropic drug LLOMe, the cell activates a regeneration pathway which helps in the formation of new functional lysosomes by recycling damaged membranes. I have identified the molecules important for this novel pathway of lysosomal regeneration and showed how the protein TBC1D15 orchestrates this process to regenerate functional organelles from completely damaged membrane masses in the first 2 hours following lysosomal membrane damage. This process resembles the process of auto- lysosomal reformation (ALR)- involving the formation of lysosomal tubules which are extended along microtubules and cleaved in a dynamin2 dependent manner to form proto-lysosomes which develop into fully functional mature lysosomes. These lysosomal tubules are closely associated with ATG8 positive autophagosomal membranes and require ATG8 proteins to bind to the lysophagy receptor LIMP2 on damaged membranes. This process is physiologically important under conditions of crystal nephropathy where calcium oxalate crystals induce damage to lysosomal membranes in nephrons in kidney disease.
The second part of the thesis shows how the endolysosomal system of the cell is hijacked by the bacteriaLegionella pneumophila. During Legionella infection the formation of conventional ATG8 positive autophagosomes are blocked due to the protease activity of the bacterial effector protein RavZ which cleaves lipidated ATG8 proteins from autophagosomal membranes. The SidE effectors of Legionella modify STX17 and SNAP29 by the process of non-canonical ubiquitination called phosphoribose-linked serine ubiquitination (PR-Ub). These proteins are essential for the formation of the autophagosomal SNARE complex which is used for fusion of the autophagosome with the lysosome. Upon Legionella infection, PR-UB of STX17 aids in formation of autophagosome-like replication vacuoles. ThesevacuolesdonotfusewiththelysosomebecauseSNAP29isalsoPR-Ubmodified. PR-UbofSTX17 and SNAP29 sterically blocks the formation of the autophagosomal-SNARE complex thereby preventing fusion of the autophagosome with the lysosome. As a result, Legionella can replicate in autophagosome- like vacuoles which do not undergo lysosomal degradation. In absence of PR-Ub modified STX17, bacterial replication is compromised when measured by bacterial replication assays in lung epithelial (A549) cells.
Taken together, this thesis highlights two important aspects of the autophagy-lysosomal system- how it responds to extensive membrane damage and its importance in Legionella pneumophila infection. Extensive damage to lysosomal membranes triggers a rapid regeneration process to partially restore lysosomal function before the effects of TFEB dependent lysosomal biogenesis becomes apparent. On the other hand, Legionella pneumophila infection segregates the lysosomes from the rest of the endo-lysosomal system by blocking autophagosome-lysosome fusion. Though lysosomes remain active, they are incapable of degrading pathogens since pathogen containing vacuoles do not fuse with the lysosome.
This thesis comprises the usage of two commonly known hinge-binding moieties in drug discovery. First, the quinazoline scaffold of gefitinib (5) was utilized in a macrocyclization strategy to introduce selectivity. In general, the quinazoline hinge-binding moiety is a commonly used scaffold which can be found in 14% of approved kinase inhibitors. The most familiar applications are EGFR inhibitors such as gefitinib (5), erlotinib (6), afatinib, or dacomitinib for the treatment of NSCLC. But other kinases like CDK2, CDK4, or p38 are reported targets as well.
The N-phenylquinazolin-4-amine moiety of gefitinib (5) was conserved however, the residues at the aromatic ring in the linker were modified, the residue targeting the solvent-exposed region was varied, and the linker at the C6 position of the quinazoline was adjusted to enable the macrocyclization. An overview of the structural modifications is shown in Figure 35A.
Kinome-wide screening of gefitinib (5) revealed several off-targets besides EGFR (Figure 35B), making it an excellent starting point for a macrocyclization strategy. Introducing a linker to the N phenylquinazoline-4-amine scaffold and retaining the residues on the aromatic ring as well as the methoxy group targeting the solvent-exposed region improved the selectivity profile and the efficacy towards EGFR WT and its mutants. Truncation of the linker moiety led to the mutant selective macrocycle 26f with an excellent kinome-wide selectivity profile (Figure 35B). An inhibitor that is effective on EGFR mutations while ineffective on the EGFR WT could represent an enhancement of patient treatment, as it potentially causes less side effects. Further studies could determine the effect of the most promising macrocycles in lung cancer cell lines. Additionally, the pharmacokinetic properties could be optimized, e.g. by introducing solubilizing groups, targeting the solvent-exposed region.
The second scaffold comprises the 3-aminopyrazole-based hinge-binding moiety. It is a privileged scaffold in medicinal chemistry for the development of kinase inhibitors. Previous publications report the anti-proliferative and anti-cancer potential of pyrazole-based molecules. They play a crucial role in the treatment of various diseases and cancer types like inflammation disorders, lymphoma, or breast cancer. This scaffold can be found e.g. in the aurora kinase inhibitor tozasertib or in the promiscuous kinase inhibitor 23, published by Statsuk et. al. Rescreening compound 23 in a comprehensive kinase panel against 468 human protein kinases confirmed the unselective behavior with a selectivity score of S35 = 0.56 (Figure 36B), making it a great starting point for further optimizations. The N-(1H-pyrazol-3-yl)pyrimidin-4-amine scaffold was conserved however, the residues targeting the solvent-exposed region were varied and different linkers were attached.
The introduction of different residues at the pyrazole dramatically influenced the selectivity profile of the desired kinases. Ester moieties caused to a favorable combination of selectivity and potency towards the kinase of interest CDK16. The removal of additional residues at the pyrimidine, targeting the solvent-exposed region, increased the efficiency towards CDK16. Further optimization led to the highly potent and selective CDK16 inhibitor 98d (IC50 = 33 nM). NanoBRETTM screening against the complete CDK family revealed a preferred inhibition of the PCTAIRE and PFTAIRE subfamily with cellular IC50 values of 20 nM – 120 nM and 50 nM – 180 nM, respectively. A FUCCI cell cycle assay and viability assessment of 98d confirmed previously published results, reporting a G2/M cell cycle arrest followed by apoptosis and accumulation of p27 through knockout of CDK16 in SCC cells. Consequently, further studies could evaluate the anti-tumor activity of 98d in SCC and NSCLC or elucidate the effect of 98d in AMPK-related macroautophagy. 98d represents a novel tool compound to investigate the understudied kinases of the PCTAIRE family and enable to enlighten the biological role of those kinases.
Macrocyclization of the N-(1H-pyrazol-3-yl)pyrimidin-4-amine core resulted in the selective BMPR2 inhibitor 110a. It showed a good binding affinity towards BMPR2 with a KD value of 205 nM as well as a good potency with an IC50 value of 506 nM. A comprehensive selectivity screen against 468 kinases revealed an excellent selectivity profile with S35 = 0.01. As no BMPR2 inhibitors have been published so far, 110a represents a novel compound that may provide further insights into the canonical BMP pathway, noncanonical signaling, or its impact on BMPR2-associated diseases like PAH.
The introduction of additional residues targeting the solvent-exposed region shifted the selectivity towards the MST kinases. The exchange from the pyrimidine to a quinazoline moiety resulted in the highly potent and selective macrocyclic MST3 inhibitor 113c. NanoBRETTM measurements demonstrated the preferred inhibition of MST3 with IC50 values of 210 nM and 30 nM for intact and lysed cells, respectively. A weaker activity could be seen for MST4 with 1.8 µM and 510 nM, while MST1 and MST2 were not affected. To date, no selective MST3 inhibitors have been published, making 113c a valuable tool compound for further functional studies. As MST3 is influencing the cell cycle progression, 113c could be tested in a further cell cycle assay to elucidate the inhibitory effect of 113c on MST3 and consequently on the cell cycle. Furthermore, the anti-tumor activity of 113c in breast cancer could be determined, as Madsen et. al. reported a high MST3 and MST4 activity triggered by FAM40B mutations.
The ability of some knotless phytochromes to photoconvert without the PHY domain allows evaluation of the distinct effect of the PHY domain on their photodynamics. Here, we compare the ms dynamics of the single GAF domain (g1) and the GAF-PHY (g1g2) construct of the knotless phytochrome All2699 from cyanobacterium Nostoc punctiforme. While the spectral signatures and occurrence of the intermediates are mostly unchanged by the domain composition, the presence of the PHY domain slows down the early forward and reverse dynamics involving chromophore and protein binding pocket relaxation. We assign this effect to a more restricted binding pocket imprinted by the PHY domain. The photoproduct formation is also slowed down by the presence of the PHY domain but to a lesser extent than the early dynamics. This indicates a rate limiting step within the GAF and not the PHY domain. We further identify a pH dependence of the biphasic photoproduct formation hinting towards a pKa dependent tuning mechanism. Our findings add to the understanding of the role of the individual domains in the photocycle dynamics and provide a basis for engineering of phytochromes towards biotechnological applications.
Mechanism of the MHC I chaperone TAPBPR and its role in promoting UGGT1-mediated quality control
(2022)
Information about the health status of most nucleated cells is provided through peptides presented on major histocompatibility complex I (pMHC I) on the cell surface. T cell receptors of CD8+ T cells constantly monitor these complexes and allow the immune system to detect and eliminate infected or cancerous cells. Antigenic peptides displayed on MHC I are typically derived from the cellular proteome and are translocated into the lumen of the endoplasmic reticulum (ER) by the ATP-binding cassette (ABC) transporter associated with antigen processing (TAP), which is part of the peptide-loading complex (PLC). In a process called peptide editing, the MHC I-dedicated chaperone tapasin (Tsn) selects peptides for their ability to form stable complexes with MHC I. While initial peptide loading is catalyzed in the confines of the PLC, the second quality control is mediated by TAPBPR, operating in the peptide-depleted cis-Golgi network. TAPBPR was shown to have a more fine-tuning effect on the presented peptide repertoire rather than initial peptide selection. The fundamental mechanism of peptide editing was illuminated by two crystal structures of TAPBPR in complex with peptide-receptive MHC I. Notably, one of these structures reported a structural element that inserted into the peptidebinding pocket. The so-called scoop loop was assumed to be involved in mediating peptide exchange but the underlying mechanism remained undefined. Additionally, latest results suggested that TAPBPR mediates the interaction of the glucosyltransferase UGGT1 with peptide-receptive MHC. To expand the current knowledge of quality control processes in the antigen presentation pathway, the contribution of the scoop loop in peptide editing and the role of TAPBPR in UGGT1-mediated quality control needs to be elucidated. In the first part of this study, TAPBPR proteins with various loop lengths were designed to scrutinize the contribution of the scoop loop in chaperoning peptidereceptive MHC I. In a light-driven approach, the ability of TAPBPR variants to form stable complexes with peptide-free MHC I was tested. These results demonstrated that in a peptide-depleted environment, the scoop loop is of critical importance for TAPBPR to chaperone intrinsically unstable, peptidereceptive MHC I clients. Moreover, fluorescence polarization-based assays allowed the pursuit of peptide exchange in different, native-like environments. Peptide displacement activities of TAPBPR variants illustrated that catalyzed peptide editing is primarily induced by structural elements outside the scoop loop. In a peptide-depleted environment, the scoop loop occupies the position of the peptide C-terminus and acts as an internal peptide surrogate. By combining complex formation and fluorescence polarization experiments, the scoop loop of TAPBPR was shown to be critically important in stabilizing empty MHC I and functions as an internal peptide selector. In the second part of this study, a novel in-vitro glucosylation assay was established to examine the role of TAPBPR in UGGT1-catalyzed re-glucosylation of TAPBPR-bound MHC I clients. Therefore, a peptide-free MHC I-TAPBPR complex with defined glycan species was designed which served as physiological substrate for UGGT1. By subjecting the recombinantly expressed HLA-A*68:02- TAPBPR complex and UGGT1 proteins to the new in-vitro system, UGGT1 was shown to catalyze the transfer of a glucose residue to the N-linked glycan of TAPBPR-bound Man9GlcNAc2-HLA-A*68:02. Moreover, a high-affinity, photocleavable peptide was applied to dissociate the MHC I-chaperone complex. However, in the absence of TAPBPR, no glucosyltransferase activity was observed. Generation of peptide-free MHC I through UV illumination also showed no activity, and only the addition of TAPBPR could restore UGGT1-mediated reglucosylation of the empty MHC I. Independent of the peptide status of HLAA*68:02, the combination of protein glycoengineering and LC-MS analysis implicated that UGGT1 exclusively acts on TAPBPR-chaperoned HLA-A*68:02. The newly established system provided insights into the function of TAPBPR during UGGT1-catalyzed re-glucosylation activity and quality control of MHC I. Taken together, the scoop loop allows TAPBPR to function as MHC I chaperone through stabilizing peptide-receptive MHC I. In a peptide-depleted environment, the loop structure serves as an internal peptide surrogate and can only be dislodged by a high-affinity peptide. Based on these findings, TAPBPR fulfills a dual function in the second level of quality control. On the one hand, TAPBPR functions as peptide editor, shaping the repertoire of presented peptides. On the other hand, TAPBPR mediates peptide-receptive MHC I clients to the folding sensor UGGT1. Here, TAPBPR is essential to promote UGGT1-catalyzed reglucosylation of the N-linked glycan, giving MHC I a second chance to be loaded with an optimal peptide cargo in the peptide loading complex.
Electrospinning is a versatile and promising drug delivery technology for the development of tailor-made drug delivery systems for various clinical applications. By applying high voltages to drug-loaded polymer solutions, solid polymeric nanofibers can be generated, which encapsulate active pharmaceutical ingredients (APIs) into their polymer matrix. During the electrospinning process, the fibers are deposited on a collector and form a nonwoven network of drug-loaded polymer fibers. These fibers are spatially distributed in aligned or random orientation, providing the opportunity to design highly tunable structural and mechanical properties, which can be adapted to the biological requirements of the intended application site. The mechanically flexible fiber networks can therapeutically be administered to a multitude of pharmaceutical application sites. Their highly porous fiber structure exhibits a large surface-to-volume ratio, which is ideal for controlled drug release kinetics from the polymer matrix upon contact with biological fluids, such as tear fluid, saliva, mucus, wound exudate or gastro-intestinal fluid. For application at the target site, fiber mats are cut into patches. As the patch size determines the quantity of applied API, the electrospinning process must ensure homogeneous distribution of the API throughout the entire fiber mat area.
In this thesis, electrospinning was established as a formulation technology for the rational fabrication of tailor-made multifunctional drug carrier systems for local and site-specific drug delivery to the epithelial interfaces skin, oral mucosa as well as cornea. For adequate characterization and analysis of the drug delivery systems, a broad panel of robust and predictive analytical tools, based of novel investigation techniques for physicochemical characterization of electrospun fibers, was developed.
The initial part of the thesis thematically focuses on the development of predictive analytical techniques, to determine fiber morphology and physicochemical properties, as well as fiber composition and drug release. By designing two model formulations with contrasting properties, and subsequent analysis and characterization with a set of newly developed techniques and state-of-the-art methods, a comprehensive toolset has been made available and evaluated, aiming at advancing and standardizing respective techniques in the scientific field of electrospun drug delivery systems.
Starting with the initiation of the electrospinning formulation process, which often relies on empirical data rather than analytical methods to predict successful processability, analysis of rheological properties of electrospinning solutions was used to rationally detect the minimum polymer concentration required for electrospinning.
For analysis of fiber morphology, scanning electron microscopy is a common technique. However, little attention is given to underlying readout parameters. By analyzing the fiber orientation and diameter of the respective fibers, predictive results regarding mechanical properties could be obtained, which were subsequently confirmed by measuring elongation force with tensile testing. Confocal Raman microscopy, a label-free method for chemically- selective imaging of the fiber samples, was introduced as a complementary visualization technique, enabling the detection of fiber composition and drug distribution.
A novel technique for investigation of water contact angles on the fiber surface of highly hydrophilic polymers was introduced, which provides predictive data regarding interaction with body fluids and the resulting drug release kinetics. Subsequent release testing in a newly developed setup for analyzing drug release from electrospun fibers in low-volume body compartments, confirmed the anticipated drug release kinetics from measurement of the surface hydrophilicity.
By combining complementary analytical methods, including spectral composition analysis, morphology visualization, characterization of physico-chemical properties and drug release kinetics, as well as the application of multivariate data analysis, a robust and predictive toolset has been established, which can support comparability of future electrospinning studies and the translation from the lab bench into clinics.
Based on the analytical toolset, the main part of the thesis focuses on the development and preparation of electrospun platform drug delivery systems for application on epithelial barriers. Electrospun fiber mats are thin, flat, and mechanically flexible, which allows close adherence to epithelial surfaces and reduction of diffusion paths, which enables efficient drug delivery to the skin, oral mucosa, as well as the cornea.
Electrospun fibers bear a high potential for application as wound dressings, while simultaneously controlling the local delivery of APIs to the wound area. Their close resemblance to the extracellular matrix of human skin provides a suitable microenvironment for cellular proliferation and migration for wound closure. In this work, insulin, a fragile proteohormone with growth factor characteristics, was successfully encapsulated into the core of coaxially electrospun fibers, thus maintaining bioactivity throughout and after the electrospinning process. The shell has been designed from biocompatible polymers, which, upon contact with aqueous wound exudate, partially dissolve and form pores through which bioactive insulin is released in a controlled manner. The shell layer provides a hydrophilic surface for interaction with body fluids and skin cells, and possesses substantial mechanical strength, flexibility, and high tensile elongation required for application on wounds. The biocompatibility of the wound dressing was investigated by interaction with primary human dermal fibroblasts and keratinocytes, which displayed healthy cell morphologies without indicating any elevated levels of cytotoxicity markers.
To investigate the effect of insulin on cell migration, in vitro scratch assays on human skin cells were performed. Increased cellular migration speed and wound closure could be observed, indicating improved wound healing. Bio relevance of in vitro wound healing potential results was advanced by development of 3D ex vivo human epidermal skin wound models from reduction surgery donor material. These complex wound models were treated with electrospun insulin fibers and analyzed by proteome analysis to reveal significant increases in wound healing-associated signaling pathways, which could be attributed to a material-driven remarkably positive impact on wound healing of the electrospun fibers...
Cyclic GMP (cGMP) is a second messenger that regulates numerous physiological and pathophysiological processes. In recent years, more and more studies have uncovered multiple roles of cGMP signalling pathways in the somatosensory system. Accumulating evidence suggests that cGMP regulates different cellular processes from embryonic development through to adulthood. During embryonic development, a cGMP-dependent signalling cascade in the trunk sensory system is essential for axon bifurcation, a specific form of branching of somatosensory axons. In adulthood, various cGMP signalling pathways in distinct cell populations of sensory neurons and dorsal horn neurons in the spinal cord play an important role in the processing of pain and itch. Some of the involved enzymes might serve as a target for future therapies. In this review, we summarise the knowledge regarding cGMP-dependent signalling pathways in dorsal root ganglia and the spinal cord during embryonic development and adulthood, and the potential of targeting these pathways.
LINKED ARTICLES
This article is part of a themed issue on cGMP Signalling in Cell Growth and Survival. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v179.11/issuetoc
Mixed-valence compounds as polarizing agents for overhauser dynamic nuclear polarization in solids
(2021)
Herein, we investigate a novel set of polarizing agents—mixed-valence compounds—by theoretical and experimental methods and demonstrate their performance in high-field dynamic nuclear polarization (DNP) NMR experiments in the solid state. Mixed-valence compounds constitute a group of molecules in which molecular mobility persists even in solids. Consequently, such polarizing agents can be used to perform Overhauser-DNP experiments in the solid state, with favorable conditions for dynamic nuclear polarization formation at ultra-high magnetic fields.
The concept of using precipitation inhibitors (PIs) to sustain supersaturation is well established for amorphous formulations but less in the case of lipid-based formulations (LBF). This study applied a systematic in silico–in vitro–in vivo approach to assess the merits of incorporating PIs in supersaturated LBFs (sLBF) using the model drug venetoclax. sLBFs containing hydroxypropyl methylcellulose (HPMC), hydroxypropyl methylcellulose acetate succinate (HPMCAS), polyvinylpyrrolidone (PVP), PVP-co-vinyl acetate (PVP/VA), Pluronic F108, and Eudragit EPO were assessed in silico calculating a drug–excipient mixing enthalpy, in vitro using a PI solvent shift test, and finally, bioavailability was assessed in vivo in landrace pigs. The estimation of pure interaction enthalpies of the drug and the excipient was deemed useful in determining the most promising PIs for venetoclax. The sLBF alone (i.e., no PI present) displayed a high initial drug concentration in the aqueous phase during in vitro screening. sLBF with Pluronic F108 displayed the highest venetoclax concentration in the aqueous phase and sLBF with Eudragit EPO the lowest. In vivo, the sLBF alone showed the highest bioavailability of 26.3 ± 14.2%. Interestingly, a trend toward a decreasing bioavailability was observed for sLBF containing PIs, with PVP/VA being significantly lower compared to sLBF alone. In conclusion, the ability of a sLBF to generate supersaturated concentrations of venetoclax in vitro was translated into increased absorption in vivo. While in silico and in vitro PI screening suggested benefits in terms of prolonged supersaturation, the addition of a PI did not increase in vivo bioavailability. The findings of this study are of particular relevance to pre-clinical drug development, where the high in vivo exposure of venetoclax was achieved using a sLBF approach, and despite the perceived risk of drug precipitation from a sLBF, including a PI may not be merited in all cases.
The function of the p53 transcription factor family is dependent on several folded domains. In addition to a DNA-binding domain, members of this family contain an oligomerization domain. p63 and p73 also contain a C-terminal Sterile α-motif domain. Inhibition of most transcription factors is difficult as most of them lack deep pockets that can be targeted by small organic molecules. Genetic knock-out procedures are powerful in identifying the overall function of a protein, but they do not easily allow one to investigate roles of individual domains. Here we describe the characterization of Designed Ankyrin Repeat Proteins (DARPins) that were selected as tight binders against all folded domains of p63. We determine binding affinities as well as specificities within the p53 protein family and show that DARPins can be used as intracellular inhibitors for the modulation of transcriptional activity. By selectively inhibiting DNA binding of the ΔNp63α isoform that competes with p53 for the same promoter sites, we show that p53 can be reactivated. We further show that inhibiting the DNA binding activity stabilizes p63, thus providing evidence for a transcriptionally regulated negative feedback loop. Furthermore, the ability of DARPins to bind to the DNA-binding domain and the Sterile α-motif domain within the dimeric-only and DNA-binding incompetent conformation of TAp63α suggests a high structural plasticity within this special conformation. In addition, the developed DARPins can also be used to specifically detect p63 in cell culture and in primary tissue and thus constitute a very versatile research tool for studying the function of p63.
Druggability Evaluation of the Neuron Derived Orphan Receptor (NOR-1) Reveals Inverse NOR-1 Agonists
(2022)
The neuron derived orphan receptor (NOR-1, NR4A3) is among the least studied nuclear receptors. Its physiological role and therapeutic potential remain widely elusive which is in part due to the lack of chemical tools that can directly modulate NOR-1 activity. To probe the possibility of pharmacological NOR-1 modulation, we have tested a drug fragment library for NOR-1 activation and repression. Despite low hit-rate (<1 %), we have obtained three NOR-1 ligand chemotypes one of which could be rapidly expanded to an analogue comprising low micromolar inverse NOR-1 agonist potency and altering NOR-1 regulated gene expression in a cellular setting. It confirms druggability of the transcription factor and may serve as an early tool to assess the role and potential of NOR-1.
We propose a generalized modeling framework for the kinetic mechanisms of transcriptional riboswitches. The formalism accommodates time-dependent transcription rates and changes of metabolite concentration and permits incorporation of variations in transcription rate depending on transcript length. We derive explicit analytical expressions for the fraction of transcripts that determine repression or activation of gene expression, pause site location and its slowing down of transcription for the case of the (2’dG)-sensing riboswitch from Mesoplasma florum. Our modeling challenges the current view on the exclusive importance of metabolite binding to transcripts containing only the aptamer domain. Numerical simulations of transcription proceeding in a continuous manner under time-dependent changes of metabolite concentration further suggest that rapid modulations in concentration result in a reduced dynamic range for riboswitch function regardless of transcription rate, while a combination of slow modulations and small transcription rates ensures a wide range of finely tuneable regulatory outcomes.
Riboswitches are gene regulatory elements located in untranslated mRNA regions. They bind inducer molecules with high affinity and specificity. Cyclic-di-nucleotide-sensing riboswitches are major regulators of genes for the environment, membranes and motility (GEMM) of bacteria. Up to now, structural probing assays or crystal structures have provided insight into the interaction between cyclic-di-nucleotides and their corresponding riboswitches. ITC analysis, NMR analysis and computational modeling allowed us to gain a detailed understanding of the gene regulation mechanisms for the Cd1 (Clostridium difficile) and for the pilM (Geobacter metallireducens) riboswitches and their respective di-nucleotides c-di-GMP and c-GAMP. Binding capability showed a 25 nucleotide (nt) long window for pilM and a 61 nt window for Cd1. Within this window, binding affinities ranged from 35 μM to 0.25 μM spanning two orders of magnitude for Cd1 and pilM showing a strong dependence on competing riboswitch folds. Experimental results were incorporated into a Markov simulation to further our understanding of the transcriptional folding pathways of riboswitches. Our model showed the ability to predict riboswitch gene regulation and its dependence on transcription speed, pausing and ligand concentration.
Protein biosynthesis is a fundamental process across all domains of life. Polypeptides are produced by translating the genetic information of the messenger RNA (mRNA) into amino acids. This elaborate procedure is divided into the four distinct phases: initiation, elongation, termination, and ribosome recycling. The phases are controlled and regulated by a multitude of translation factors. During initiation, the ribosome assembles on the mRNA. Initiation factors (IFs) bind to the small ribosomal subunit (SSU) and assist the recruitment of mRNA and initiator transfer RNA (tRNA), which delivers the first amino acid methionine. After positioning the SSU at the start codon of the mRNA, additional IFs support the joining of the large ribosomal subunit (LSU). Next, elongation factors (EFs) deliver amino-acylated tRNAs (aa-tRNAs) to the translating ribosome and assist kinetic proofreading and ribosome subunit translocation after the catalytic transfer of the polypeptide onto the aa-tRNA. When a stop codon is reached, translation is terminated by release factors (RFs) that hydrolyze the peptidyl-tRNA to release the nascent protein chain. Afterwards, the ribosome is recycled in Eukaryotes and Archaea by the conserved and essential factor ABCE1, which splits the ribosome into the LSU and SSU. ABCE1 remains bound to the SSU forming the post-splitting complex (post-SC). mRNA translation closes into a cycle by recruitment of IFs to the post-SC and the start of a new round of initiation. The post-SC presents the platform for translation initiation. However, the role of ABCE1 in initiation remains elusive. Therefore, the main goal of my thesis was to unravel the molecular mechanism of ABCE1 on the post-SC and during initiation complex (IC) assembly.
Using a reconstituted system, the high-resolution structure of the archaeal post-SC was solved by cryogenic electron microscopy (cryo-EM) following the native splitting route. It was the first complete model of an archaeal SSU at atomic resolution and revealed a previously undescribed ribosomal protein, which we termed eS21. The hinge 2 region of ABCE1 was identified to be the major interaction interface that anchors to the SSU. Functional characterization of single residue mutations in hinge 2 unraveled essential interactions with the ribosomal RNA backbone of the SSU. Sensing of SSU-binding was found to be allosterically transmitted to the nucleotide-binding sites (NBSs) for integration into the ATPase cycle of ABCE1.
Reconstitution of the archaeal translation apparatus allowed for dissection of IC assembly in the presence of ABCE1. Three different ICs were resolved by cryo-EM. The results were in accordance with recent structural findings of eukaryotic translation initiation and highlighted that the involvement of ABCE1 is conserved.
In a semi-native approach, recombinant ABCE1 was pulled-down from crenarchaeal cell lysates. Mass spectrometric analysis of co-immunoprecipitated ribosomal complexes identified the association of numerous translation factors to the post-SC in a cellular context. The establishment of the genetic toolbox of the acidothermophilic Sulfolobus acidocaldarius allowed the homologous expression of ABCE1. Pull-down of native ABCE1 revealed similar ribosomal complexes as the semi-native and reconstituted approaches. Together, my results gave first physiological relevance of ABCE1 involvement in mRNA translation initiation in Archaea. Native archaeal ABCE1-ICs were vitrified for structural analysis by cryo-EM. Thereby, future structural analysis will allow to analyze the interactions of ABCE1 on native ICs and identify its role in IC assembly.
To address the molecular process of IC assembly, the binding affinity of aIF1 to the SSU was determined by fluorescence polarization. Similar studies will allow for a detailed functional analysis on IF recruitment to the SSU in presence of ABCE1.
mRNA surveillance and ribosome-associated quality control (RQC) mechanisms evolved to ensure cell viability. The pathways overcome ribosome stalling and defective translation components. Stalled ribosomes are terminated by special RFs, which do not hydrolyze the peptidyl-tRNA, but allow dissociation of the ribosome by ABCE1. Faulty messages are degraded via mRNA decay pathways and the LSU is rescued by RQC factors. Recently, the bacterial RQC factor MutS2 was identified to specifically target collided di- and polysomes but its molecular mechanism remains unknown. In this thesis, initial functional analyses showed tri-phosphate specific nucleotide binding of MutS2. While the dissociation of collided disomes by MutS2 could not be observed, the results pave the way for future in vitro studies of bacterial RQC factors acting on specific ribosome populations.
In the future, mRNA translation research must focus on complex quality control processes to comprehensively understand this fundamental cellular process in a holistic context.
Protein kinases are key signalling molecules and transduce intracellular signals via the post-translational phosphorylation of substrate proteins, often other protein kinases. Dysregulation of this protein family has been linked to many diseases including neurodegenerative diseases, inflammation and cancer and amplifications of kinases play important roles as diagnostic biomarkers in a variety of cancers. Various strategies have been developed to treat dysregulated protein kinases. Most commonly, chemical small molecule inhibitors are used to modulate protein kinase activity in cancer cells. Many inhibitor and general research efforts have focused only on a small subset of protein kinases, resulting in a large portion of the kinome, the so-called “dark” kinome, remaining largely unexplored. As part of the strategy to develop inhibitors, it is crucial to understand the structure-activity-relationships (SAR) of small molecules to the activity towards the targets based on understanding small molecule-target affinities as determined by biophysical, biochemical, and cellular methods. However, not always do in vitro determined affinities, which are frequently used as basis for SAR considerations, correlate with the cellular affinity. For protein kinases in particular, it has been shown that the cellular concentration of the natural substrate adenosine-triphosphate (ATP) plays a critical role for the resulting small molecule affinity, as substrate and inhibitor frequently compete for the same binding site of the protein kinase. The cellular target engagement assay NanoBRET is a versatile assay that overcomes this problem and can be used to assess binding of a compound to the full-length protein kinase, in the presence of natural binding partners. Another important factor in inhibitor optimization is the selectivity of the molecule within the family of protein kinases. When comparing the selectivity profiles of small molecule kinase inhibitors in vitro and in cells, different profiles can be observed. Frequently, a compound, binds fewer protein kinases with high affinity in cells, indicating that cellular profiling of protein kinase inhibitors is necessary to understand the selectivity profile of an inhibitor.
The goal of this work was to understand cellular SARs of inhibitors for kinases and dark kinases in medicinal chemistry projects, and to understand the selectivity profiles of existing small molecules in cells, including already approved drugs and clinically used kinases inhibitors. The cellular potency and selectivity aspects guided optimization of the inhibitors towards selective small molecules ‘chemical probes’ or highly validated inhibitors with a narrow selectivity profile as part of ‘chemogenomic libraries’. One strategy to improve selectivity has been to use sterically restricted cyclic small molecules, called macrocycles, that allow fewer conformations of the molecule than their non-cyclic parent compound. In this thesis the dark kinase STK17A was investigated. Macrocyclization was used to develop a selective chemical probe molecule that is also selective in the cellular context. For another kinase, SIK2, a rational design approach was used to exclude off-targets bound by the lead structure, resulting in a chemical probe that selectively targets the SIK1/2/3 proteins. Assessing cellular potency of another series of inhibitors, a probe was developed for the PCTAIRE subfamily of the CDK kinases. This required co-expression of the binding partners of CDKs, the cyclins, in cells to obtain a functional assay. To identify new candidates for the neglected family of splicing kinases comprising the CLK, SRPK, DYRK and HIPK protein kinase subfamilies, a literature review was conducted, and the best small molecule candidates were compared for their target engagement in cells. This led to a series of small molecule inhibitors that may be used as a set or single agents to target the CLK proteins and SRPK proteins or in combination to target the remaining proteins. In search of new starting points for this subfamily of kinases, an initial screen with NanoBRET technology was performed using a library of over 2000 inhibitors, and new starting points were identified. Additionally, a set of clinical and approved small molecule kinase inhibitors was assessed for their selectivity in cells. Several highly selective molecules were identified that were much less selective in in vitro approaches. The set of data allowed for a comprehensive comparison of cellular potencies with published data using in vitro binding, in vitro activity and data obtained from cell lysates and identified several protein kinases that would need to be investigated in cells...
Ribosomes catalyze protein synthesis by cycling through various functional states. These states have been extensively characterized in vitro, yet their distribution in actively translating human cells remains elusive. Here, we optimized a cryo-electron tomography-based approach and resolved ribosome structures inside human cells with a local resolution of up to 2.5 angstroms. These structures revealed the distribution of functional states of the elongation cycle, a Z tRNA binding site and the dynamics of ribosome expansion segments. In addition, we visualized structures of Homoharringtonine, a drug for chronic myeloid leukemia treatment, within the active site of the ribosome and found that its binding reshaped the landscape of translation. Overall, our work demonstrates that structural dynamics and drug effects can be assessed at near-atomic detail within human cells.
Single-particle electron cryo-microscopy (cryoEM) has undergone a `resolution revolution' that makes it possible to characterize megadalton (MDa) complexes at atomic resolution without crystals. To fully exploit the new opportunities in molecular microscopy, new procedures for the cloning, expression and purification of macromolecular complexes need to be explored. Macromolecular assemblies are often unstable, and invasive construct design or inadequate purification conditions and sample-preparation methods can result in disassembly or denaturation. The structure of the 2.6 MDa yeast fatty acid synthase (FAS) has been studied by electron microscopy since the 1960s. Here, a new, streamlined protocol for the rapid production of purified yeast FAS for structure determination by high-resolution cryoEM is reported. Together with a companion protocol for preparing cryoEM specimens on a hydrophilized graphene layer, the new protocol yielded a 3.1 Å resolution map of yeast FAS from 15 000 automatically picked particles within a day. The high map quality enabled a complete atomic model of an intact fungal FAS to be built.
De novo fatty acid biosynthesis in humans is accomplished by a multidomain protein, the type I fatty acid synthase (FAS). Although ubiquitously expressed in all tissues, fatty acid synthesis is not essential in normal healthy cells due to sufficient supply with fatty acids by the diet. However, FAS is overexpressed in cancer cells and correlates with tumor malignancy, which makes FAS an attractive selective therapeutic target in tumorigenesis. Herein, we present a crystal structure of the condensing part of murine FAS, highly homologous to human FAS, with octanoyl moieties covalently bound to the transferase (MAT) and the condensation (KS) domain. The MAT domain binds the octanoyl moiety in a novel (unique) conformation, which reflects the pronounced conformational dynamics of the substrate binding site responsible for the MAT substrate promiscuity. In contrast, the KS binding pocket just subtly adapts to the octanoyl moiety upon substrate binding. Besides the rigid domain structure, we found a positive cooperative effect in the substrate binding of the KS domain by a comprehensive enzyme kinetic study. These structural and mechanistic findings contribute significantly to our understanding of the mode of action of FAS and may guide future rational inhibitor designs.
Cyclic di-AMP is the only known essential second messenger in bacteria and archaea, regulating different proteins indispensable for numerous physiological processes. In particular, it controls various potassium and osmolyte transporters involved in osmoregulation. In Bacillus subtilis, the K+/H+ symporter KimA of the KUP family is inactivated by c-di-AMP. KimA sustains survival at potassium limitation at low external pH by mediating K+ ions uptake. However, at elevated intracellular K+ concentrations, further K+ accumulation would be toxic. In this study, we reveal the molecular basis of how c-di-AMP binding inhibits KimA. We report cryo-EM structures of KimA with bound c-di-AMP in detergent solution and reconstituted in amphipols. By combining structural data with functional assays and molecular dynamics simulations we reveal how c-di-AMP modulates transport. We show that an intracellular loop in the transmembrane domain interacts with c-di-AMP bound to the adjacent cytosolic domain. This reduces the mobility of transmembrane helices at the cytosolic side of the K+ binding site and therefore traps KimA in an inward-occluded conformation.
Modular polyketide synthases (PKSs) produce complex, bioactive secondary metabolites in assembly line-like multistep reactions. Longstanding efforts to produce novel, biologically active compounds by recombining intact modules to new modular PKSs have mostly resulted in poorly active chimeras and decreased product yields. Recent findings demonstrate that the low efficiencies of modular chimeric PKSs also result from rate limitations in the transfer of the growing polyketide chain across the non-cognate module:module interface and further processing of the non-native polyketide substrate by the ketosynthase (KS) domain. In this study, we aim at disclosing and understanding the low efficiency of chimeric modular PKSs and at establishing guidelines for modular PKSs engineering. To do so, we work with a bimodular PKS testbed and systematically vary substrate specificity, substrate identity, and domain:domain interfaces of the KS involved reactions. We observe that KS domains employed in our chimeric bimodular PKSs are bottlenecks with regards to both substrate specificity as well as interaction with the ACP. Overall, our systematic study can explain in quantitative terms why early oversimplified engineering strategies based on the plain shuffling of modules mostly failed and why more recent approaches show improved success rates. We moreover identify two mutations of the KS domain that significantly increased turnover rates in chimeric systems and interpret this finding in mechanistic detail.
In recent years, the incidence of infected wounds is steadily increasing, and so is the clinical as well as economic interest in effective therapies. These combine reduction of pathogen load in the wound with general wound management to facilitate the healing process. The success of current therapies is challenged by harsh conditions in the wound microenvironment, chronicity, and biofilm formation, thus impeding adequate concentrations of active antimicrobials at the site of infection. Inadequate dosing accuracy of systemically and topically applied antibiotics is prone to promote development of antibiotic resistance, while in the case of antiseptics, cytotoxicity is a major problem. Advanced drug delivery systems have the potential to enable the tailor-made application of antimicrobials to the side of action, resulting in an effective treatment with negligible side effects. This review provides a comprehensive overview of the current state of treatment options for the therapy of infected wounds. In this context, a special focus is set on delivery systems for antimicrobials ranging from semi-solid and liquid formulations over wound dressings to more advanced carriers such as nano-sized particulate systems, vesicular systems, electrospun fibers, and microneedles, which are discussed regarding their potential for effective therapy of wound infections. Further, established and novel models and analytical techniques for preclinical testing are introduced and a future perspective is provided.
Mechanistic and structural insights into the quality control of the MHC I antigen processing pathway
(2022)
The human body is permanently exposed to its environment and thus to viruses and other pathogens, which require a flexible response and defense. Alongside to the innate immune system, the adaptive immune system provides highly specialized protection against these threats. The major histocompatibility complex class I (MHC I) antigen presentation system is a cornerstone of the adaptive immune system and a major constituent of cellular immunity. Pathogens such as viruses that invade a cell will leave traces in the form of proteins and peptides which are degraded and loaded onto MHC I molecules. MHC I peptide loading is performed by peptide loading complex (PLC) in the membrane of the endoplasmic reticulum as part of a multifaceted and comprehensive quality control machinery. Monitored by multiple layers of quality assurance, the MHC I molecules consequently display the immune status of the cell on its surface. In this context, the captured fragment of the virus serves as a call for help issued by the cell, alerting the adaptive immune system to the infection to mount an appropriate immune response.
The three-dimensional structure as well as the mechanistic details of parts of this complex machinery were characterized in the context of this dissertation. Among other tools, light-modulable nanotools were developed in this thesis, which permit external regulation of cellular processes in temporal and spatial resolution. Furthermore, methods and model systems for the biochemical characterization of cellular signaling cascades, proteins, as well as entire cell organelles were developed, which are likely to influence the field of cellular immunity and protein biochemistry in the future.
This cumulative work comprises a total of six publications whose scientific key advances will be briefly outlined in this abstract. In the introduction, the scientific background as well as the current state of research and methodological background knowledge are conveyed. The results section condenses the main aspects of the publications and links them to each other. Further details can be retrieved from the attached original publications.
In “Semisynthetic viral inhibitor for light control of the MHC I peptide loading complex, Winter, Domnick et al., Angew Chem Int Ed 2022” a photocleavable viral inhibitor of the peptide loading complex was produced by semi-synthesis. This nanotool was shown to be suitable for both purifying the PLC from human Raji cells as well as reactivating it in a light-controlled manner. Thus, this tool establishes the isolation of a fully intact and functional peptide loading complex for biochemical characterization. In addition, a novel flow cytometric analysis pipeline for microsomes was developed, allowing cellular vesicles to be characterized with single organelle resolution, similar to cells.
In “Molecular basis of MHC I quality control in the peptide loading complex, Domnick, Winter et al., Nat Commun 2022” the peptide loading complex was reconstituted into large nanodiscs, and a cryo-EM structural model of the editing module at 3.7 Å resolution was generated. By combining the structural model with in vitro glycan editing assays, an allosteric coupling between peptide-MHC I assembly and glycan processing was revealed, extending the known model of MHC I loading and dissociation from the PLC. These mechanisms provide a prototypical example for endoplasmic reticulum quality control.
In a related context, in “Structure of an MHC I–tapasin–ERp57 editing complex defines chaperone promiscuity, Müller, Winter et al., Nat Commun 2022” a recombinantly assembled editing module comprised of MHC I-tapasin-ERp57 was crystallized for X-ray structural biology. The resulting crystal structure at a resolution of 2.7 Å permitted the precise identification of characteristic features of the editing module and particularly of the peptide proofreading mechanism of tapasin. This study provided pivotal insights into the tapasin-mediated peptide editing of different MHC I allomorphs as well as similarities to TAPBPR-based MHC I peptide proofreading.
In “TAPBPR is necessary and sufficient for UGGT1-mediated quality control of MHC I, Sagert, Winter et al. (in preparation)” novel insights concerning the peptide proofreader TAPBPR and its close interplay with the folding sensor and glucosyltransferase UGGT1 were obtained. It was shown that TAPBPR is an integral part of the second level of endoplasmic quality control and is indispensable for effective MHC I coordination by UGGT1.
In “Light-guided intrabodies for on-demand in situ target recognition in human cells, Joest, Winter et al., Chem Sci 2021” intracellular nanobodies were equipped with a photocaged target recognition domain by genetic code expansion via amber suppression. These intrabodies, acting as high-affinity binding partners endowed with a fluorophore, could be used in a light-triggered approach to instantaneously visualize their target molecule...
This work investigated the influence of the CRISPR/Cas9 mediated knockout of 5-lipoxygenase (5-LO) on different adherent tumour cell lines derived from solid tumours. For this, the 5-LO expressing tumour cell lines HCT-116, HT-29, and U-2 OS were transiently transfected using a plasmid carrying the CRISPR/Cas9 complex sequence to the ALOX5 gene. Subsequently, cells were selected using Puromycin and analysed via Western blotting and DNA Sanger sequencing. Cells that were transfected with a control plasmid missing the guide RNA sequence, were used as a control for all experiments.
Differential gene expression analysis, performed after next-generation RNA sequencing, revealed that the expression of various genes was altered after the knockout of 5-LO. In HCT-116 cells, 28 genes were expressed differentially in all 5-LO knockout single-cell clones, while in HT-29 cells the expression of 18 genes and in U-2 OS cells of 234 genes was influenced by the knockout of 5-LO. These findings were validated by real-time qPCR. A lot of the genes that were influenced by the 5-LO knockout are known to be connected to epithelial-mesenchymal-transition (EMT), a process necessary for tumour metastasis. The results from RNA sequencing were the starting point for further investigations. In the following, different aspects of the tumour cell lines were examined. In HT-29, as
well as in U-2 OS cells, it was shown that knockout of the 5-LO resulted in impaired cell proliferation. Also, the formation of three-dimensional tumour spheroids was altered. In HT-29 cells, the knockout of 5-LO increased the number of cells in spheroids. In contrast, in U-2 OS cells, the number of cells per spheroid was decreased, even though the diameter of the spheroids was increased, due to more loosely packed spheroids. The difference between 5-LO positive and negative U-2 OS cells became even more obvious after embedding the spheroids in an artificial extracellular matrix. In that scenario, cells lacking the 5-LO formed smaller spheroids that did not have the same ability to grow into the extracellular matrix as 5-LO positive cells did. Also, directed cell migration was strongly influenced by the knockout of 5-LO. In both, HCT-116 and U-2 OS cells, directed cell migration towards a serum gradient was increased in 5-LO knockout single-cell clones. Pharmacological inhibition of the enzyme was used to investigate, whether canonical or non-canonical functions were responsible for the previously mentioned effects.
Therefore, vector control cells were treated with the 5-LO inhibitors Zileuton and CJ-13610 in different concentrations. Interestingly, only some of the effects mediated by the complete knockout of 5-LO could be reproduced by inhibiting the enzyme, leading to the suggestion, that canonical, as well as non-canonical functions of 5-LO, play a role in these tumour cells.
To conclude, it was shown in this study, that 5-LO affects various cellular functions when expressed in adherent tumour cell lines. These cell line-dependent effects result in altered gene expression, enhanced proliferation, and spheroid formation, as well as impaired cell motility, and can be mediated by enzymatic activity as well as other non-canonical functions.
The ongoing pandemic caused by the Betacoronavirus SARS-CoV-2 (Severe Acute Respiratory Syndrome Coronavirus-2) demonstrates the urgent need of coordinated and rapid research towards inhibitors of the COVID-19 lung disease. The covid19-nmr consortium seeks to support drug development by providing publicly accessible NMR data on the viral RNA elements and proteins. The SARS-CoV-2 genome encodes for approximately 30 proteins, among them are the 16 so-called non-structural proteins (Nsps) of the replication/transcription complex. The 217-kDa large Nsp3 spans one polypeptide chain, but comprises multiple independent, yet functionally related domains including the viral papain-like protease. The Nsp3e sub-moiety contains a putative nucleic acid-binding domain (NAB) with so far unknown function and consensus target sequences, which are conceived to be both viral and host RNAs and DNAs, as well as protein-protein interactions. Its NMR-suitable size renders it an attractive object to study, both for understanding the SARS-CoV-2 architecture and drugability besides the classical virus’ proteases. We here report the near-complete NMR backbone chemical shifts of the putative Nsp3e NAB that reveal the secondary structure and compactness of the domain, and provide a basis for NMR-based investigations towards understanding and interfering with RNA- and small-molecule-binding by Nsp3e.
Ceramide synthase (CerS) is the enzyme responsible for the de novo synthesis of ceramide. In this process, the different CerS isoforms are substrate-specific and produce ceramides of different chain lengths. Ceramides form the backbone for other sphingolipids and are enriched in membrane microdomains called lipid rafts. Lipid rafts are important signaling platforms for many transmembrane proteins, but can also act as bioactive lipids. Depending on the chain length, the effects on signaling pathways can vary. The aim of this work was to further investigate the chain length-specific effects by CerS4 on the progression of inflammatory colon cancer. To understand the tissue-specific effects of CerS4 deficiency on the progression of acute colitis and colitis-associated cancer (CAC), CerS4 knockout models were used. Disease progression of wild-type CerS4 (WT) was compared with that of mice with global CerS4 knockout (CerS4 KO) and mice in which CerS4 deficiency was restricted to T cells (CerS4 LCK/Cre) or intestinal cells (CerS4 Vil/Cre). Acute colitis was induced with sodium dextran sulfate (DSS), whereas azoxymethane (AOM)/DSS combinations were used to induce CAC in mice. The results showed a different disease progression depending on the specific knockout. While CerS4 KO mice were sensitive to DSS. AOM/DSS treatment was lethal for these mice, indicating an important role of CerS4 in other tissues. CerS4 Vil/Cre mice were protected from tumor formation. In contrast, CerS4 LCK/Cre mice experienced increased tumor formation and pan-inflammation. The mechanism behind this is due to the absence of cytotoxic T cells and the increase of regulatory T cells in the CerS4 LCK/Cre mice, demonstrating that CerS4 is critical for T cell function and development. To understand the role of CerS in humans, organoids were prepared from patients and the CerS profile in the different organoids was elucidated. This work provides, for the first time, insights into the CerS profile in human organoids and demonstrates a link between differentiation markers and stem cell markers with CerS. In addition, the role of CerS4 was investigated in vitro using three different colon cell lines-Caco-2 cells, HCT116 cells, and HCT15 cells. Hypoxia induced downregulation of CerS4 in all cell lines. Using the luciferase promoter assay, hypoxia-induced downregulation could already be detected at the promoter. Downregulation of CerS4 and CerS5 in Caco-2 cells and HCT116 cells resulted in different metabolic changes and mitochondrial dynamics after hypoxia. In conclusion, the results show that the role of CerS4 depends on the tissue cell type and stage of colorectal carcinoma, which complicates the consideration of CerS4 as a target in patients.
Die vorliegende Arbeit mit dem Titel Multiphoton Processes and Photocontrol of Biochemical Reaction Pathways befasst sich mit verschiedenen Strategien zur Implementierung von optischer Kontrolle in biochemisch relevanten Systemen. Auf systemischer Ebene wurde einerseits die Licht-getriebene Natriumpumpe Krokinobacter Eikastus Rhodopsin 2 (KR2) vor dem Hintergrund optogenetischer Anwendungen untersucht, und andererseits die Optimierung der wichtigsten photochemischen Parameter von photolabilen Schutzgruppen (PPG, engl. photolabile protecting group) angestrebt. Von der technisch-photophysikalischen Seite wurde ein weiterer Fokus auf den Aktivierungs- und Deaktivierungsschritt gelegt. Hierbei wurden vor allem Mehrphotonen-Prozesse betrachtet, die entweder durch simultane Absorption zweier Photonen zu einer spezifischen hoch-energetischen Anregung führen, oder durch sequentielle Absorption eine sukzessive Aktivierung und Deaktivierung eines Systems bewerkstelligen können. Auch wenn der Schwerpunkt dieser schriftlichen Arbeit auf den spektroskopischen Ergebnissen liegt, waren alle hier diskutierten Projekte stark kollaborativ und umfassten eine große Bandbreite verschiedener Techniken. Dies spiegelt den interdisziplinären Charakter vieler aktueller Fragestellungen in der photochemischen Forschung wider, die - in vielen Fällen - letztlich auf medizinische oder pharmazeutische Fortschritte abzielen.
Zunächst wurde die lichtgetriebene Natriumpumpe KR2 untersucht, die durch ihre mögliche Anwendung als optogenetisches Werkzeug bekannt wurde. In einer vergleichenden Studie der Natrium- und Protonenpumpmodi von KR2 konnten wichtige mechanistische Prinzipien für die Funktionalität des Proteins identifiziert werden. Dazu gehört die direkte Beteiligung spezifischer Strukturmerkmale wie die Aminosäure N112 und/oder der ECL1-Domäne am Ionen-Translokationsweg, sowie das enge Zusammenspiel zwischen dem Retinal und seinem Gegenion D116. Gleichzeitig bot diese IR-Studie einen der ersten mechanistischen Einblicke in den Protonenpump-Photozyklus in KR2, der deutlich weniger erforscht war. In Zusammenarbeit mit dem Arbeitskreis Glaubitz wurden die strukturellen Veränderungen des Chromophors und seiner Umgebung während der verschiedenen Photointermediate mittels DNP-verstärkter Festkörper-NMR und optischer Spektroskopie näher untersucht. Hier trugen zeitaufgelöste IR-Messungen in der HOOP (engl. hydrogen out of plane)-Moden-Region dazu bei, die dynamischen Veränderungen der Chromophorkonfiguration und -Verdrillung zu verfolgen. Es konnte gezeigt werden, dass Retinal im O-Intermediat tatsächlich zu seiner all-trans-Konfiguration reisomerisiert wird, aber im Vergleich zu seiner Dunkelzustandskonfiguration deutlich stärker verdreht vorliegt.
Dies wurde auch durch die Ergebnisse im nahen UV-Bereich bestätigt, welcher bei der Charakterisierung von mikrobiellen Rhodopsinen oft ausgelassen wird. Die neu gefundene Signatur erwies sich als SBS (engl. second bright state) der 13-cis-Konfiguration des Retinals, die mit der Bildung des O-Intermediats in KR2 verschwindet. Neben der offensichtlichen Verwendung als spektraler Marker wurde der SBS-Übergang auch bezüglich seiner Anwendbarkeit für optische Kontrollexperimente untersucht. Ähnlich wie beim BLQ (engl. blue light quenching)-Effekt war es möglich, den KR2-Dunkelzustand durch Anwendung von fs-Pulsen im nahen UV - ausgehend von einem photostationären Zustand - zu regenerieren. Durch Variation der Probenbedingungen war es möglich, gezielt K (pH~5) oder M (pH~9) anzusteuern, was sich auch in unterschiedlichen Deaktivierungs-Dynamiken äußerte. Diese Ergebnisse können zusammen mit dem hier vorgeschlagenen experimentellen Konzept als Grundlage für komplexere Multiphotonen-Sequenzen im Zusammenhang optogenetischer Fragestellungen verwendet werden.
Im Gegensatz zu den recht großen und komplexen Photorezeptoren bieten unter anderem PPGs einen feineren Weg, um biochemische Reaktionen gezielt zu steuern und auszulesen. In diesem Zusammenhang sind zwei Eigenschaften von großer Bedeutung: Einerseits die Fähigkeit der PPG, Photonen bestimmter Wellenlängen zu absorbieren, und andererseits die Effizienz der gewünschten photochemischen Reaktion. Der letztgenannte Aspekt wurde unter der Hypothese untersucht, dass die Verringerung der konkurrierenden Deaktivierungskanäle in PPGs zu einer höheren Quantenffizienz der Freisetzung führt. Dies wurde an DEACM-basierten Modellverbindungen getestet, die systematisch modifiziert wurden, um verschiedene Deaktivierungsprozesse des angeregten Zustands zu identifizieren. Durch das Hinzufügen eines zusätzlichen sechsgliedrigen Rings wurde die Freisetzungsausbeute im Vergleich zu DEACM um das 2- bis 3-fache erhöht. Dies konnte durch eine weitere Planarisierung des Systems mit einer zusätzlichen Doppelbindung an der C6-Position sogar noch weiter verbessert werden (bis zu einem Faktor von 5-6). Die Anregung des Cumarin-Rückgrats führt zu einem lokal-angeregten Zustand, der sich im Gleichgewicht mit einem Ladungstransferzustand befindet. In Abhängigkeit der lokalen Umgebung, die vor allem durch die Protizität und Polarität des Lösungsmittels bestimmt wird, wird der Ladungstransfercharakter eher stabilisiert oder gar destabilisiert. Die Ladungsverschiebung führt auch zu einer Abschwächung der spaltbaren C-C-Bindung, die eine Voraussetzung für die Freisetzungsreaktion ist. Darüber hinaus wurde gezeigt, dass der mit der Freisetzungsreaktion verbundene zusätzliche Zerfallskanal zu einer mehr als 2-fachen Verringerung der Lebensdauer des angeregten Zustands in den funktionalisierten PPGs führt. Diese Eigenschaft ist ein vielversprechender photophysikalischer Indikator für die Freisetzung der Abgangsgruppe, der durch spektroskopische oder - mit zusätzlicher räumlicher Auflösung - auch durch mikroskopische Techniken wie in der Fluoreszenzlebensdauer-Mikroskopie ausgelesen werden könnte...
Zika virus (ZIKV) is a member of the Flaviviridae family that received public attention and scientific interest after the outbreak in French Polynesia (2013-2014) and the epidemic in the Americas (2015-2016). Even though only 20% of infected people exhibit clinical manifestations and they are predominantly flu-like symptoms, these events unveiled neurological complications associated with ZIKV infection, such as the Guillain-Barré syndrome in adults and microcephaly in newborns. Lacking a preventive vaccine and a specific antiviral therapy against ZIKV allied to the fact that this pathogen is a re-emerging virus, uncovering and comprehending novel virus-host interactions is crucial to the identification of new antiviral targets and the development of innovative antiviral approaches. Previous research work uncovered that the Chinese hamster ovary (CHO) cells do not support ZIKV infection.459 As this cell line does not express endogenous epidermal growth factor receptor (EGFR), this study aimed to investigate whether EGFR and EGFR-dependent signaling are relevant for the ZIKV life cycle in vitro.
In the first part of the study, viral infection was investigated in CHO cells and compared to A549 cells, a highly ZIKV permissive cell line. After performing binding and entry assays, ZIKV entry, but not the attachment, was significantly decreased in CHO cells in comparison to A549 cells. Additionally, in A549-EGFR KO cells, ZIKV entry was diminished relatively to the off-target control. These results show the clear impact that the absence of EGFR has on viral entry, implicating EGFR during this process. Even though EGFR overexpression in CHO cells could not render these cells permissive to ZIKV infection, as demonstrated by the lack of viral infection after electroporation with in vitro transcribed capped ZIKV-Renilla luciferase RNA, it was possible to rescue ZIKV entry. These findings suggest that there are additional elements, which are not expressed in CHO cells, required for viral replication.
Furthermore, the impact of ZIKV infection on EGFR mRNA and protein levels as well as on the EGFR subcellular localization and distribution was evaluated. The relative number of EGFR specific transcripts continuously increased with ZIKV infection, whereas the EGFR protein level diminished at later times of infection. Moreover, changes in the subcellular localization of EGFR and its colocalization with the early endosomal marker EEA1 in ZIKV-infected cells revealed that ZIKV triggers EGFR internalization. The relevance of EGFR in the ZIKV entry process was further corroborated by the observation of EGFR internalization at 30 min post-infection (mpi) and to less extent at 60 mpi, which concurs with the expected time of ZIKV entry into the host cells.
In the remaining part of the study, the influence of ZIKV infection in EGFR-dependent signaling as well as the contribution of EGFR and EGFR signaling for viral infection were studied. Activation of EGFR and the MAPK/ERK signaling cascade was detected as early as 5 mpi and ceased within 30 mpi in ZIKV-infected cells. Taking into account that EGFR internalization was observed at 30 mpi in infected cells, the activation of EGFR and ERK and subsequent dephosphorylation within this period go along with this previous observation. Vice-versa, inhibition of the activation of EGFR and the MAPK/ERK pathway declines ZIKV infection. On the one hand, inhibition of EGFR activation by Erlotinib affected ZIKV entry, as a consequence of impaired EGFR internalization. On the other hand, Raf and MEK inhibitors reduced ZIKV infection without disturbing viral replication or viral entry. These data suggest that the activation of the MAPK/ERK signaling cascade is necessary for a step of the viral life cycle before the onset of genome replication and morphogenesis and after viral entry. The importance of EGFR signaling was additionally investigated by the determination of EGFR half-life in ZIKV-infected cells upon EGF stimulation. While the EGFR half-life was similar in uninfected and Uganda-infected cells, a delay in EGFR degradation was observed in French Polynesia-infected cells. This observation might indicate an extended usurpation of the EGFR signaling since EGFR seems to still be active in the endosomes. Moreover, disruption of lipid rafts by MβCD, a cholesterol-depleting agent, hampered ZIKV entry. In uninfected cells, MβCD treatment led to the activation of EGFR, but at the same time prevented EGFR internalization, indicating that EGFR activation exclusively is not sufficient for an efficient ZIKV entry and further supporting the importance of EGFR internalization during the ZIKV entry process.
Taken together, this study uncovers EGFR as a relevant host factor in the early stages of ZIKV infection, providing novel insights into the ZIKV entry process. Since numerous monoclonal antibodies and substances that target EGFR are licensed, repurposing these compounds might be a helpful tool for the establishment of an antiviral therapy in case of ZIKV re-emergence.
Diseases such as cardiac arrhythmias, CPVT and other issues of the human heart still remain largely unexplored. To contribute to this field of research, it is necessary to create tools to control the spatial and temporal release and reuptake of Ca2+ from the sarcoplasmic/endoplasmic reticulum (SR/ER). Ca2+ release and uptake by the ryanodine receptor (RyR) and Sarcoplasmic/endoplasmic reticulum calcium ATPase (SERCA), respectively, are essential for the function of excitable cells. In this process, the rapid Ca2+ release from the SR/ER and the associated contraction in muscle cells is modulated by RyR. However, diseases due to calcium leakage, such as cardiac arrhythmias, seizures and contractile dysfunction, are also caused by RyR. The resting Ca2+ concentration in the cytosol, which is important for the cell, is kept in balance by Ca2+ release and reuptake into the SR/ER. This reuptake is controlled quite considerably by SERCA. SERCA is important for development and muscle function in both nematodes such as C. elegans and mammals, though there is also a great need for tools that can help study precise function.
To advance towards the goal of developing tools for optogenetic stimulation of intracellular Ca2+ release from the SR/ER, the model organism C. elegans was chosen. Its advantages are the fully sequenced genome and the neural network connectome. In addition, the ease of maintenance, self-fertilisation, transparency and rapid generation cycles, as well as the fact that it is a eutelic animal, are advantages for the application of the optogenetic approach.
So far, tools for light-induced Ca2+ release (LICR) have already been developed, involving the creation of ChR2 versions with higher Ca2+ conductivity based on the "CatCh" variant and further improving their conductivity through several established mutations. In addition, the pharynx of C. elegans was modified to produce an optogenetically stimulated muscle pump that resembles mammalian cardiac muscle cells. In this work, both optoUNC-68 (optically excitable RyR) and SERCA/LOV2 were generated in different variants by CRISPR/Cas9 and plasmid-based genome editing to achieve light-driven manipulation of calcium homeostasis in C. elegans. Here, LICR was triggered by LOV2 domains in an opto-mechanical manipulation of RyR as well as SERCA. This approach was made possible by recently published high-resolution cryoEM structural images. In addition, alternative approaches using Ca2+ conductance-optimised channelrhodopsin variants were tested in C. elegans body wall muscle cells.
By inserting ChR-XXM into C. elegans and subsequent fluorescence microscopy of the co-introduced GFP, an expression in body wall muscle cells could be detected. Furthermore, in contraction assays, ChR-XXM was demonstrated to induce contractions of the animals of up to 16% compared to the original body length in both medium (0.8mW/mm²) and high (1.4mW/mm²) stimulation at 470nm. ChR-XXM was thus identified as an excellent candidate for the development of an optogenetic tool, as it exhibits significantly increased Ca2+ conductivity compared to other ChR2 variants.
The use of CRISPR/Cas9 to insert AsLOV2 domains (L404-L546) into different insertion sites of RyR allowed the generation of a transgenic strain of C. elegans that could be stimulated to elongate during 0.3mW/mm² photostimulation. This demonstrated that RyR can be manipulated by photostimulation, spatiotemporally through conformational changes in the LOV2 domain and the resulting disruption of the pore region.
The CRISPR/Cas9 method was also used to insert LOV2 domains into SERCA. Here it could be demonstrated that a conformational change of the LOV2 domains induced by photostimulation leads to a stop or impairment of Ca2+ ion translocation by SERCA from the cytosol into the SR/ER. In contrast to LOV2 in RyR, this resulted in a contraction of C. elegans body length.
The data presented here indicate that the intracellular Ca2+ cycle involving the SR/ER and cytosol can be successfully manipulated by the introduction of optogenetic tools. It turned out that the manipulation/impairment of individual components of this system, such as RyR or SERCA, is usually insufficient to achieve a clear response. Therefore, simultaneous manipulation of the two main actors RyR and SERCA is arguably the best way to take another step towards creating optogenetic tools for light-stimulated manipulation of Ca2+ release and reuptake from the SR/ER.
Membrane proteins are a diverse group of proteins that serve a multitude of purposes with one of the most important ones being transport. All kinds of substrates are shuffled over biological membranes with the help of dedicated proteins enabling the transport along and against a concentration gradient. Within the group of actively transporting proteins a diverse set of proteins that rely on an electrochemical gradient to facilitate transport of a substrate against its concentration gradient can be found. Those so-called secondary active
transporters are a group on integral membrane proteins ubiquitous to all cells. They allow the transport of all kinds of substrates like nutrients, ions, other metabolites and drugs over the hydrophobic barrier created by the cellular and organellar membrane. The gradients that provide the main driving force for most of the transporters are either sodium ions or protons, although transporters utilizing other ions or organic compounds are found as well. In case of exchangers two very similar substrates are transported in opposing direction over the membrane, one against its electrochemical gradient driven by the other.
Along with a structural diversity of the transporters concerning overall shape, oligomerization and number of transmembrane elements comes a mechanistic variety though still following the principle of alternating access. In humans the malfunction of secondary active transporters can lead to a physiological disorders such as epilepsy, depression or obesity.
The focus of this thesis was the structural and functional characterization of the secondary active transporter SeCitS from Salmonella enterica, a symporter of the 2-hydroxycarboxylate family. The transport of citrate as a bivalent ion is facilitated by the flux of sodium ions that have an inward-facing gradient over the inner membrane of Salmonella enterica. Transport experiments showed that the transport ratio is two sodium ions per citrate molecule, netting in an electroneutral transport. Compared to other members of the family the specificity of the transporter towards its main substrate is very high.
Structural information on the protein was initially obtained through 2D electron crystallography, which allowed the identification of the oval shaped dimer and a first hint towards a significant conformational change that the protein undergoes during its transport cycle. Using 3D crystallography, the X-ray structure of the transporter was solved. The protein crystalizes as a stable, but conformationally asymmetric dimer. As bound citrate can be readily identified in both protomers they can be assigned into an outward- and an inward-facing conformation, with the main citrate binding site in the outward-facing conformation.
One interesting feature of the crystal structure was the large surface available for multimerization, providing a platform for tight dimerization of the two protomers. On the other hand, SeCitS did not show a true cooperativity of transport. With those two aspects taken into account the question arose if any potential crosstalk between the monomers within the dimer takes place and influences transport (negative cooperativity) or the conformational distribution within the dimer (stabilization of the protein within the membrane).
The functional approach in answering this question was the use of mutated variants of the protein for cross-linking within one monomer. Two residues were chosen respectively to lock one of either conformation to be able to test for transport activity in the remaining protomer. The suitability of the residues was derived from the crystal structure (D112 – R205 to lock the inward-facing conformation and L337 – S412 for the outward-facing conformation). After initial promising results the final variants were not stable enough to be analyzed in transport assays.
To analyze the distribution of relative conformations within the dimer the protein was reconstituted into native-like lipid environment such as nanodiscs or saposin nanoparticles to be analyzed by cryo-electron microscopy. The first images were recorded and did yield promising 2D classes where the general features of the transporter were identified. Yet, an improved preparation is required to obtain a high resolution structure.
The key functional aspects of a transporter are its ability to bind and transport its substrates. In a set of experiments those features were investigated by a radioligand transport assay and by isothermal titration calorimetry (ITC). The transport properties of the protein were assessed in a filter assay using a radioactively labeled citrate as a read-out. The protein was reconstituted into proteoliposomes and subjected to different substrate conditions. Different ions were tested in its ability to drive or inhibit transport, but only sodium ions were able to drive transport and also not hindered by the presence of other ions...
In the last twenty years, there has been splendid progress in energy conversion technologies to have sustainable energy sources. For example, solar cells contribute significantly to energy production as the sun is an enormous source for renewable energy. Currently, the most common commercialized photovoltaic devices are silicon-based. The scientists' main targets are high efficiency, low cost, environmentally friendly, and easy to synthesize new semiconductor materials to replace silicon. Furthermore, understanding the photophysical properties of these materials is very important for designing high efficient photoconversion systems.
This thesis investigates the photophysics of lead-based wide-bandgap perovskites with different dimensionality (2D, 3D) and how they can be optimized for optoelectronic applications. In chapter 1, we present the background and progress in perovskite research. The basic concepts of semiconductor and spectroscopic methods of the applied techniques in this work are discussed in chapter 2.
In the first project (chapter 3.1), we used our time-resolved techniques to study the ultrafast dynamics of energy transfer from the inorganic to the organic layer in a series of three lead-based mixed-halide 2D perovskites containing benzyl ammonium (BA), 1-naphthyl methyl ammonium (NMA), and 1-pyrene methyl ammonium (PMA) thin films.
In the second project (chapter 3.2), we used time-resolved spectroscopic techniques to study the effect of adding 5% of Cs on the dynamics of a mixed-cation wide bandgap bromide-based 3D perovskite.
In another side project (chapter 4), we present the photophysics properties of newly synthesized new Schiff bases containing indole moieties using piperidine as an organic base catalyst and Au@TiO2 as a heterogeneous catalyst. Finally, the results of this work are summarized in Chapter 5 with an outlook and a discussion of open questions for further research.
NMR structure calculation using NOE-derived distance restraints requires a considerable number of assignments of both backbone and sidechains resonances, often difficult or impossible to get for large or complex proteins. Pseudocontact shifts (PCSs) also play a well-established role in NMR protein structure calculation, usually to augment existing structural, mostly NOE-derived, information. Existing refinement protocols using PCSs usually either require a sizeable number of sidechain assignments or are complemented by other experimental restraints. Here, we present an automated iterative procedure to perform backbone protein structure refinements requiring only a limited amount of backbone amide PCSs. Already known structural features from a starting homology model, in this case modules of repeat proteins, are framed into a scaffold that is subsequently refined by experimental PCSs. The method produces reliable indicators that can be monitored to judge about the performance. We applied it to a system in which sidechain assignments are hardly possible, designed Armadillo repeat proteins (dArmRPs), and we calculated the solution NMR structure of YM4A, a dArmRP containing four sequence-identical internal modules, obtaining high convergence to a single structure. We suggest that this approach is particularly useful when approximate folds are known from other techniques, such as X-ray crystallography, while avoiding inherent artefacts due to, for instance, crystal packing.
Cardiolipin, the mitochondria marker lipid, is crucially involved in stabilizing the inner mitochondrial membrane and is vital for the activity of mitochondrial proteins and protein complexes. Directly targeting cardiolipin by a chemical-biology approach and thereby altering the cellular concentration of “available” cardiolipin eventually allows to systematically study the dependence of cellular processes on cardiolipin availability. In the present study, physics-based coarse-grained free energy calculations allowed us to identify the physical and chemical properties indicative of cardiolipin selectivity and to apply these to screen a compound database for putative cardiolipin-binders. The membrane binding properties of the 22 most promising molecules identified in the in silico approach were screened in vitro, using model membrane systems finally resulting in the identification of a single molecule, CLiB (CardioLipin-Binder). CLiB clearly affects respiration of cardiolipin-containing intact bacterial cells as well as of isolated mitochondria. Thus, the structure and function of mitochondrial membranes and membrane proteins might be (indirectly) targeted and controlled by CLiB for basic research and, potentially, also for therapeutic purposes.
A toolbox for the generation of chemical probes for Baculovirus IAP Repeat containing proteins
(2022)
E3 ligases constitute a large and diverse family of proteins that play a central role in regulating protein homeostasis by recruiting substrate proteins via recruitment domains to the proteasomal degradation machinery. Small molecules can either inhibit, modulate or hijack E3 function. The latter class of small molecules led to the development of selective protein degraders, such as PROTACs (PROteolysis TArgeting Chimeras), that recruit protein targets to the ubiquitin system leading to a new class of pharmacologically active drugs and to new therapeutic options. Recent efforts have focused on the E3 family of Baculovirus IAP Repeat (BIR) domains that comprise a structurally conserved but diverse 70 amino acid long protein interaction domain. In the human proteome, 16 BIR domains have been identified, among them promising drug targets such as the Inhibitors of Apoptosis (IAP) family, that typically contain three BIR domains (BIR1, BIR2, and BIR3). To date, this target area lacks assay tools that would allow comprehensive evaluation of inhibitor selectivity. As a consequence, the selectivity of current BIR domain targeting inhibitors is unknown. To this end, we developed assays that allow determination of inhibitor selectivity in vitro as well as in cellulo. Using this toolbox, we have characterized available BIR domain inhibitors. The characterized chemical starting points and selectivity data will be the basis for the generation of new chemical probes for IAP proteins with well-characterized mode of action and provide the basis for future drug discovery efforts and the development of PROTACs and molecular glues.
The SARS-CoV-2 (SCoV-2) virus is the causative agent of the ongoing COVID-19 pandemic. It contains a positive sense single-stranded RNA genome and belongs to the genus of Betacoronaviruses. The 5′- and 3′-genomic ends of the 30 kb SCoV-2 genome are potential antiviral drug targets. Major parts of these sequences are highly conserved among Betacoronaviruses and contain cis-acting RNA elements that affect RNA translation and replication. The 31 nucleotide (nt) long highly conserved stem-loop 5a (SL5a) is located within the 5′-untranslated region (5′-UTR) important for viral replication. SL5a features a U-rich asymmetric bulge and is capped with a 5′-UUUCGU-3′ hexaloop, which is also found in stem-loop 5b (SL5b). We herein report the extensive 1H, 13C and 15N resonance assignment of SL5a as basis for in-depth structural studies by solution NMR spectroscopy.
Focused electron and ion beam induced deposition (FEBID/FIBID) methods have gained significant attention in recent years because of their unique ability for the maskless fabrication of arbitrary three-dimensional shapes. Both techniques enable material deposition down to the nanoscale for applications in materials science and condensed matter physics. However, the number of suitable precursor molecules, especially for high purity deposits, is usually still very limited to date. Additionally, both the FEBID and FIBID process are very complex when assessed in detailed and the development of process-optimize, tailored precursor molecules is not yet possible.
In the first part of this work hexacarbonyl vanadium (V(CO)6) and dimanganese decacarbonyl (Mn2(CO)10) are investigated for their use in FEBID in order to complement the already existing data on transition metal carbonyl precursors. In addition, chemical vapor deposition (CVD) has been carried out to compare compositional differences for electron induced and purely thermal processes. FEBID using V(CO)6 resulted in the formation of a vanadium (oxy)carbide material with a V:C ratio of approx. 0.6-0.9. The material shows a temperature-dependent normalized electrical conductance typical for granular metals in agreement with TEM analysis. Additionally, characterization of the crystalline fractions reveals a cubic VC1-xOx phase in agreement with the phase observed in CVD thin films. Thermal decomposition using CVD yielded material of higher purity with V:C ratios of 1.1-1.3. In contrast, an insulating material with approx. 40 at% Mn is obtained for FEBID using Mn2(CO)10 as precursor with very similar compositions being observed for CVD thin films.
The second part of this work deals with the deposition of defined alloy materials by focused charged particle beam deposition. Three silyl substituted transition metal carbonyl complexes have been synthesized and tested for FEBID, FIBID and CVD. The three precursors investigated were: H3SiMn(CO)5, H3SiCo(CO)4, and H2Si(Co(CO)4)2. FEBID experiments with the manganese derivative show the selective loss of silicon, and metal/metalloid contents of up to 49 at%. Contrary, material derived from both cobalt derivatives did retain the 1:1 and 2:1 Co:Si ratios respectively, resulting in metal/metalloid contents of up to 62 at%. Temperature-dependent normalized electrical conductance measurements of as-grown and post-growth electron beam irradiated samples reveal behavior typical for granular metals except for the as-grown CoSi material which is located on the insulating side of the metal-insulator transition. Ga+-FIBID revealed H2Si(Co(CO)4)2 to be a very suitable precursor, retaining the predefined Co:Si ratio in the deposits, while significant loss of silicon was observed for H3SiCo(CO)4 derived deposits. Contrary to FEBID high metal/metalloid contents of up to 90 at% are obtained. Additionally, temperature dependent electrical properties of dicobalt silicide and the expected ferromagnetic behavior have been observed for the Co2Si-FIBID material. Further analysis enables the proposition of different dominating decomposition channels in FEBID and FIBID based on microstructural features such as bubble formation in FIBID materials.
Inflammation or injury to the somatosensory nervous system may result in chronic pain conditions, which affect millions of people and often cause major health problems. Emerging lines of evidence indicate that reactive oxygen species (ROS), such as superoxide anion or hydrogen peroxide, are produced in the nociceptive system during chronic inflammatory and neuropathic pain and act as specific signaling molecules in pain processing. Among potential ROS sources in the somatosensory system are NADPH oxidases, a group of electron-transporting transmembrane enzymes whose sole function seems to be the generation of ROS. Interestingly, the expression and relevant function of the Nox family members Nox1, Nox2, and Nox4 in various cells of the nociceptive system have been demonstrated. Studies using knockout mice or specific knockdown of these isoforms indicate that Nox1, Nox2, and Nox4 specifically contribute to distinct signaling pathways in chronic inflammatory and/or neuropathic pain states. As selective Nox inhibitors are currently being developed and investigated in various physiological and pathophysiological settings, targeting Nox1, Nox2, and/or Nox4 could be a novel strategy for the treatment of chronic pain. Here, we summarize the distinct roles of Nox1, Nox2, and Nox4 in inflammatory and neuropathic processing and discuss the effectiveness of currently available Nox inhibitors in the treatment of chronic pain conditions.
As one of the most widespread infectious diseases in the world, it is currently estimated that approximately 296 million people globally are chronically infected with Hepatitis B virus (HBV), the consequences of HBV infection cause more than 620,000 deaths each year. Although safe and effective HBV vaccines have reduced the incidence of new HBV infections in most countries, there are still around 1.5 million new infections each year. HBV remains a major health problem because there is no large-scale effective vaccination strategy in many countries with a high burden of disease, many people with chronic HBV infection are not receiving effective and timely treatment, and a complete cure for chronic infection is still far from being achieved.
Since its discovery, HBV has been identified as an enveloped DNA virus with a diameter of 42 nm. For efficient egress from host cells, HBV is thought to acquire the viral envelope by budding into multivesicular bodies (MVBs) and escape from infected cells via the exosome release pathway. It is clear that HBV hijacks the host vesicle system to complete self-assembly and propagation by interacting with factors that mediate exosome formation. Consequently, the overlap with exosome biogenesis, using MVBs as the release platform, raises the possibility for the release of exosomal HBV particles. Currently, virus containing exosomal vesicles have been described for several viruses. In light of this, this study explored whether intact HBV-virions wrapped in exosomes are released by HBV-producing cells.
First, this study established a robust method for efficient separation of exosomes from HBV virions by a combination of differential ultracentrifugation and iodixanol density gradient centrifugation. Fractionation of the density gradient revealed that two populations of infectious viral particles can be separated from the culture fluids of HBV-producing cells. The population present in the low-density peak co-migrates with the exosome markers. Whereas the population that appeared in the high-density fractions was the classical HBV virions, which are rcDNA-containing nucleocapsids encapsulated by the HBV envelope.
Subsequently, the characterization of this low-density population was performed, namely the highly purified exosome fraction was systematically investigated. Relying on the detergent sensitivity of the exosome membrane and the outer envelope of the HBV virus, disruption of the exosome structure by treatment with limited detergent revealed the presence of HBsAg in the exosomes. At the same time, mild and limited NP-40 treatment of highly purified exosomes and a further combination of density gradient centrifugation resulted in the stepwise release of intact HBV virions and naked capsids from the exosomes generated by HBV-producing cells. This implies the presence of intact HBV particles encapsulated by the host membrane.
The presence of exosome-encapsulated HBV particles was consequently also verified by suppressing the morphogenesis of MVBs or exosomes. Impairment of MVB- or exosome-generation with small molecule inhibitors has significantly inhibited the release of host membrane-encapsulated HBV particles as well. Likewise, silencing of exosome-related proteins caused a diminution of exosome output, which compromised the budding efficiency of wrapped HBV.
Moreover, electron microscopy images of ultra-thin sections combined with immunogold staining visualized the hidden virus in the exosomal structure. Additionally, the presence of LHBs on the surface of exosomes derived from HBV-expressing cells was also observed.
As expected, these exosomal membrane-wrapped HBV particles can spread productive infection in differentiated HepaRG cells. In HBV-susceptible cells, as LHBs on the membrane surface, this type of exosomal HBV appeared to be uptaken in an NTCP receptor-dependent manner.
Taken together these data indicate that a fraction of intact HBV virions can be released as exosomes. This reveals a so far not described release pathway for HBV. Exosomes hijacked by HBV act as a transporter impacting the dissemination of the virus.
Signal transduction via phosphorylated CheY towards the flagellum and the archaellum involves a conserved mechanism of CheY phosphorylation and subsequent conformational changes within CheY. This mechanism is conserved among bacteria and archaea, despite substantial differences in the composition and architecture of archaellum and flagellum, respectively. Phosphorylated CheY has higher affinity towards the bacterial C-ring and its binding leads to conformational changes in the flagellar motor and subsequent rotational switching of the flagellum. In archaea, the adaptor protein CheF resides at the cytoplasmic face of the archaeal C-ring formed by the proteins ArlCDE and interacts with phosphorylated CheY. While the mechanism of CheY binding to the C-ring is well-studied in bacteria, the role of CheF in archaea remains enigmatic and mechanistic insights are absent. Here, we have determined the atomic structures of CheF alone and in complex with activated CheY by X-ray crystallography. CheF forms an elongated dimer with a twisted architecture. We show that CheY binds to the C-terminal tail domain of CheF leading to slight conformational changes within CheF. Our structural, biochemical and genetic analyses reveal the mechanistic basis for CheY binding to CheF and allow us to propose a model for rotational switching of the archaellum.
The majority of B-cell precursor acute leukemias in infants are associated with the chromosomal translocation t(4;11)(q21;q23), resulting in the fusion of the mixed-lineage leukemia (MLL) and ALL1-fused gene of chromosome 4 (AF4) genes. While the fusion protein MLL-AF4 is expressed in all t(4;11) patients and essential for leukemia progression, the distinct role of the reciprocal fusion protein AF4-MLL, that is expressed in only 50-80% of t(4;11) leukemia patients (Meyer et al., 2018), remains unclear. In addition, t(4;11) leukemia could so far exclusively be generated in vivo in the presence of AF4-MLL and independent of the co-expression of MLL-AF4 (Bursen et al., 2010).
In a multifactorial approach inhibiting histone deacetylases (HDACs) and expressing the dominant negative mutation of Taspase1 (dnTASP1), both MLL fusion proteins were targeted simultaneously to evaluate a possible cooperative effect between MLL-AF4 and AF4-MLL during the progression of leukemia. Of note, neither HDACi nor dnTASP1 expression negatively affect endogenous MLL, but rather endorse its function hampered by the MLL fusion proteins (Ahmad et al., 2014; Bursen et al., 2004; Zhao et al., 2019). The mere expression of dnTASP1 failed to induce apoptosis, whereas dnTASP1 could elevate apoptosis levels significantly in HDACi-treated t(4;11) cells underlining the therapeutic potential of co-inhibiting both MLL fusion proteins.
Next, the impact of inhibiting either MLL-AF4 or AF4-MLL in vivo was resolved using whole transcriptome analysis. In PDX cells obtained by the Jeremias Laboratory (Völse, 2020) that co-expressed both t(4;11) fusion proteins, the knock-down of MLL-AF4 revealed the down-regulation of pivotal hemato-malignant factors. The expression of dnTASP1 led to massive deregulation of cell-cycle genes in vivo. Considering that the inhibition of particularly MLL-AF4 but not AF4-MLL impaired leukemic cell growth in vivo (Völse, 2020), the results of this work suggest a cooperative effect between both fusion proteins, while the loss of AF4-MLL during leukemia progression appears not essential.
Thereafter, a possible short-term role of AF4-MLL during the establishment of t(4;11) leukemia was analyzed. For this purpose, an in vitro t(4;11) model was constructed to investigate the transforming potential of transiently expressed AF4-MLL in cells constitutively expressing MLL-AF4, putatively reflecting the situation in vivo. Due to the lack of a leukemic background of the applied cell line, the aim was to investigate the long-term potential of AF4-MLL to significantly alter the epigenome rather than mimicking the development of leukemia. Strikingly, short-term-expressed AF4-MLL in cooperation with MLL-AF4 exerted durable epigenetic effects on gene transcription and chromatin accessibility. The here obtained in vitro data suggest a clonal evolutionary process initiated by AF4-MLL in a cooperative manner with MLL-AF4. Importantly, no long-term changes in chromatin accessibility could be observed by the transient expression of either MLL-AF4 or AF4-MLL alone.
All in all, considering endogenous MLL, MLL-AF4 and AF4-MLL in a targeted treatment is a promising approach for a more tailored therapy against t(4;11) leukemia, and AF4-MLL is suggested to act in a cooperative manner with MLL-AF4 especially during the development of a t(4;11) leukemia.
The health status of every nucleated cell in the human body is monitored through peptides presented by major histocompatibility complex class I (MHC I) to T-cell receptors of CD8+ T-cells. Thereby, the adaptive immune system ensures the recognition and elimination of infected or cancerous cells. MHC I molecules comprise the polymorphic heavy chain (hc) and the light chain β2-microglobulin (β2m). More than 13,000 allomorphs of the MHC I hc have been identified. All MHC I hcs associate with β2m but differ in their binding preferences for peptides, ensuring the presentation of a large peptide pool. After maturation of MHC I hc/β2m heterodimers in the endoplasmic reticulum (ER), most of the peptide-deficient MHC I molecules are recruited to the peptide-loading complex (PLC). There, they go through peptide loading and editing before they are released as stable peptide-MHC I (pMHC I) complexes and traffic to the cell surface for antigen presentation.
During the stringent quality control of MHC I peptide loading and editing within the PLC, the chaperone tapasin in conjunction with the oxidoreductase ERp57 stabilizes peptide-receptive MHC I molecules and alters the peptide cargo for high immunogenicity by catalyzing peptide-exchange. The tapasin-homologue TAP-binding protein related (TAPBPR) is involved in downstream quality control, editing the peptide repertoire of MHC I molecules that slipped through peptide proofreading by tapasin. Both chaperones were shown to adopt similar binding-modes for MHC I, suggesting related mechanisms of peptide editing. Nevertheless, the MHC I specific chaperones operate in different subcellular locations with differing assistance. While TAPBPR mediates peptide-exchange solely in the peptide-poor environment of the cis-Golgi and ER-Golgi intermediate compartment (ERGIC), tapasin functions mainly within the PLC together with ERp57 and the lectin-like chaperone calreticulin. Calreticulin with its lectin-, arm- and C-terminal domain contacts the MHC I heterodimer, ERp57 and the C-terminal domain of tapasin, respectively. Notably, the interaction site between calreticulin and tapasin has not yet been elucidated experimentally at molecular detail. The depletion of tapasin leads to a compromised immune response and a change in the pool of peptide cargo. The numerous MHC I allomorphs vary in their plasticity and their dependence on tapasin for the loading of optimal peptides. Moreover, the conformational plasticity of MHC I correlates with their dependence on tapasin. However, the molecular basis on how tapasin edits the various MHC I allomorphs and the structural features that are essential for peptide exchange catalysis at atomic resolution remained elusive.
In the first part of this thesis, the trimeric complex of tapasin–ERp57/calreticulin was analyzed. To this end, laser induced liquid bead ionization mass spectrometry (LILBID-MS) was performed as part of a collaboration and revealed the trimeric assembly for tapasin–ERp57 and calreticulin. Furthermore, additional to a wildtype construct of calreticulin, a second construct, lacking the acidic helix of calreticulin that was found to come to close contact with tapasin, was utilized for isothermal titration calorimetry (ITC). A micromolar affinity of wildtype calreticulin to tapasin–ERp57 was determined. Previous biochemical and NMR studies utilizing the P-domain of calreticulin and solely ERp57 provided a micromolar affinity for the complex of calreticulin and ERp57. In this study, no interaction of calreticulin lacking the acidic helix with tapasin–ERp57 could be measured by ITC. However, these results undergo with findings that calreticulin lacking the acidic helix impairs the function of the PLC. Most likely, the negatively charged acidic helix is located in a groove of tapasin, carrying a more positive charge. Taken together, the functional data demonstrates the importance of the acidic helix of calreticulin for assembly of the trimeric subunit of calreticulin/tapasin–ERp57.
In the main part of this study an MHC I–tapasin–ERp57 complex was structurally analyzed. Therefore, a photo-triggered approach was chosen to assemble the transient complex of MHC I–tapasin–ERp57. Various allomorphs were screened for complex formation with the tapasin–ERp57 heterodimer after photocleavage by size exclusion chromatography (SEC), resulting in mouse MHC I H2-Db as the suited allomorph. Microseed matrix screening was performed. Crystals diffracting X-rays to a resolution of 2.7 Å were obtained showing one tetrameric tapasin–ERp57–MHC I complex per asymmetric unit.
The MHC I-chaperone structure shows molecular rearrangements upon MHC I engagement and unveils structural features of tapasin, involved in peptide-exchange catalysis...
Fragment-based screening has evolved as a remarkable approach within the drug discovery process both in the industry and academia. Fragment screening has become a more structure-based approach to inhibitor development, but also towards development of pathway-specific clinical probes. However, it is often witnessed that the availability, immediate and long-term, of a high quality fragment-screening library is still beyond the reach of most academic laboratories. Within iNEXT (Infrastructure for NMR, EM and X-rays for Translational research), a EU-funded Horizon 2020 program, a collection of 782 fragments were assembled utilizing the concept of “poised fragments” with the aim to facilitate downstream synthesis of ligands with high affinity by fragment ligation. Herein, we describe the analytical procedure to assess the quality of this purchased and assembled fragment library by NMR spectroscopy. This quality assessment requires buffer solubility screening, comparison with LC/MS quality control and is supported by state-of-the-art software for high throughput data acquisition and on-the-fly data analysis. Results from the analysis of the library are presented as a prototype of fragment progression through the quality control process.
Transfer RNAs (tRNAs) are highly structured non-coding RNAs which play key roles in translation and cellular homeostasis. tRNAs are initially transcribed as precursor molecules and mature by tightly controlled, multistep processes that involve the removal of flanking and intervening sequences, over 100 base modifications, addition of non-templated nucleotides and aminoacylation. These molecular events are intertwined with the nucleocy- toplasmic shuttling of tRNAs to make them available at translating ribosomes. Defects in tRNA processing are linked to the development of neurodegenerative disorders. Here, we summarize structural aspects of tRNA processing steps with a special emphasis on intron-containing tRNA splicing involving tRNA splicing endonuclease and ligase. Their role in neurological pathologies will be discussed. Identification of novel RNA substrates of the tRNA splicing machinery has uncovered functions unrelated to tRNA processing. Future structural and biochemical studies will unravel their mechanistic underpinnings and deepen our understanding of neurological diseases.
The KMT2A (MLL) gene rearrangements (KMT2A-r) are associated with a diverse spectrum of acute leukemias. Although most KMT2A-r are restricted to nine partner genes, we have recently revealed that KMT2A-USP2 fusions are often missed during FISH screening of these genetic alterations. Therefore, complementary methods are important for appropriate detection of any KMT2A-r. Here we use a machine learning model to unravel the most appropriate markers for prediction of KMT2A-r in various types of acute leukemia. A Random Forest and LightGBM classifier was trained to predict KMT2A-r in patients with acute leukemia. Our results revealed a set of 20 genes capable of accurately estimating KMT2A-r. The SKIDA1 (AUC: 0.839; CI: 0.799–0.879) and LAMP5 (AUC: 0.746; CI: 0.685–0.806) overexpression were the better markers associated with KMT2A-r compared to CSPG4 (also named NG2; AUC: 0.722; CI: 0.659–0.784), regardless of the type of acute leukemia. Of importance, high expression levels of LAMP5 estimated the occurrence of all KMT2A-USP2 fusions. Also, we performed drug sensitivity analysis using IC50 data from 345 drugs available in the GDSC database to identify which ones could be used to treat KMT2A-r leukemia. We observed that KMT2A-r cell lines were more sensitive to 5-Fluorouracil (5FU), Gemcitabine (both antimetabolite chemotherapy drugs), WHI-P97 (JAK-3 inhibitor), Foretinib (MET/VEGFR inhibitor), SNX-2112 (Hsp90 inhibitor), AZD6482 (PI3Kβ inhibitor), KU-60019 (ATM kinase inhibitor), and Pevonedistat (NEDD8-activating enzyme (NAE) inhibitor). Moreover, IC50 data from analyses of ex-vivo drug sensitivity to small-molecule inhibitors reveals that Foretinib is a promising drug option for AML patients carrying FLT3 activating mutations. Thus, we provide novel and accurate options for the diagnostic screening and therapy of KMT2A-r leukemia, regardless of leukemia subtype.
Die Fähigkeit der spezifischen und kontextabhängigen zellulären Adaption auf intrinsische und/oder extrinsische Signale ist das Fundament zellulärer Homöostase. Verschiedene Signale werden von Membranrezeptoren oder intrazellulären Rezeptoren erkannt und ermöglichen die molekulare Anpassung zellulärer Prozesse. Komplexe, ineinandergreifende Proteinnetzwerke sind dabei elementar in der Regulation der Zelle. Proteine und deren Funktionen werden dabei nach Bedarf reguliert und unterliegen einem ständigen proteolytischen Umsatz.
Die stimulusabhängige Gentranskription und/oder Proteintranslation nimmt hier eine zentrale Stellung ein, da die zugrundeliegende Maschinerie die Komposition und Funktion der Proteinnetzwerke entsprechend anpassen kann. Zusätzlich zur Regulation der Proteinabundanz werden Proteine posttranslational modifiziert, um deren Eigenschaften rasch zu ändern. Zu posttranslationalen Modifikationen zählen die Ubiquitinierung und/oder Phosphorylierung, welche die Proteinfunktionen hochdynamisch regulieren. Deregulierte Proteinnetzwerke werden oft mit Neurodegeneration und Autoimmun- oder Krebserkrankungen assoziiert. Auch Infektionen mit humanpathogenen Bakterien greifen stark in den Regulierungsprozess von Proteinnetzwerken und deren Funktionen ein. Die zelluläre Homöostase wird dadurch herausgefordert.
Bakterien der Gattung Salmonella sind zoonotische, gramnegative, fakultativ intrazelluläre Pathogene, welche weltweit millionenfach Salmonellen-erkrankungen hervorrufen. Von besonderer Bedeutung ist dabei Salmonella enterica serovar Typhimurium (hiernach Salmonella), welches im Menschen, meist durch mangelnde Hygienemaßnahmen, Gastroenteritis auslöst.
Immunität in Epithelzellen wird über das angeborene Immunsystem vermittelt und dient der Pathogenerkennung und -bekämpfung. Die Toll-like Rezeptoren (TLR) gehören zu den Mustererkennungsrezeptoren (pattern recognition receptors), welche spezifische mikrobielle Strukturen detektieren und eine kontextabhängige zelluläre Antwort generieren. Danger-Rezeptoren erkennen hingegen nicht direkt das Pathogen, sondern zelluläre Perturbationen, welche durch Zellschäden oder bakterielle Invasionen verursacht werden. Die intrinsische Fähigkeit der Wirtszelle, sich gegen Infektionen/Gefahren zu wehren wird dabei als zellautonome Immunität bezeichnet. Dabei nehmen induzierte proinflammatorische Signalwege und zelluläre Stressantworten eine wichtige Stellung ein. Die zelluläre Stressantwort aktiviert unter anderem die selektive Autophagie. Diese kann spezifisch aberrante Organelle, Proteine und invasive Pathogene abbauen. Ein weiterer Stresssignalweg ist die integrated stress response (ISR), welche eine selektive Proteintranslation erlaubt und damit die Auflösung des proteintoxischen Stresses ermöglicht.
Zur Penetration von Epithelzellen benötigt Salmonella ein komplexes System an Virulenzfaktoren, welches die bakterielle Internalisierung und Proliferation in der Wirtszelle ermöglicht. Salmonella nutzt dazu ein Typ-III-Sekretionssystem. Das System sekretiert bakterielle Virulenzfaktoren in die Zelle, sodass eine hochspezifische Modulierung des Wirtes erzwungen wird.
Die Virulenzfaktoren SopE und SopE2 spielen dabei eine Schlüsselrolle, da sie die Pathogenität von Salmonella maßgeblich vermitteln. Durch molekulare Mimikry von Wirts GTP (Guanosintriphosphat) -Austauschfaktoren aktivieren SopE und SopE2 die Rho GTPasen CDC42 und Rac1. GTP-geladenes CDC42 und Rac1 wiederum aktivieren das Aktinzytoskelett und stimulieren die Polymerisierung von Aktinfilamenten über den Arp2/3-Komplex an der Invasionsstelle. Das Pathogen wird dadurch in ein membranumhülltes Vesikel, die sogenannte Salmonella-containing Vakuole (SCV), aufgenommen. Die SCV stellt eine protektive, replikative, intrazelluläre Nische des Pathogens dar und wird permanent durch verschiedene Virulenzfaktoren moduliert.
Im Allgemeinen führt die Aktivierung von Mustererkennungsrezeptoren und Danger-Rezeptoren also zu einer zellulären Stressantwort und Entzündungsreaktion, wodurch es zur Bekämpfung der Infektion kommt. Inflammatorische Signalwege werden meist über den zentralen Transkriptionsfaktor NF-κB (nuclear factor 'kappa-light-chain-enhancer' of activated B-cells) vermittelt. NF-κB bewirkt die Induktion von proinflammatorischen Effektoren und Stressgenen. Zellautonome Immunität wird zusätzlich durch antibakterielle Autophagie ermöglicht, wobei Salmonella selektiv über das lysosomale System abgebaut werden. Das bakterielle Typ-III-Sekretionssystem verursacht an einigen wenigen SCVs Membranschäden, sodass Salmonella das Wirtszytosol penetrieren. Zytosolische Bakterien werden dabei spezifisch ubiquitiniert. Dies erlaubt die Erkennung durch die Autophagie-Maschinerie.
In der vorliegenden Arbeit wurde die zellautonome Immunität von Epithelzellen während einer akuten Salmonella Infektion durch quantitative Proteomik untersucht...
Die vorliegende Dissertation stellt eine Methode zur Löslichkeitsbestimmung vor, die für die Anwendung im Rahmen von BCS-Biowaiver Monografien entwickelt wurde. Der Methode und dem dafür konzipierten Studienprotokoll liegt das Prinzip der „Minimallöslichkeit“ zugrunde. Damit lässt sich einfach, kosteneffizient und wissenschaftlich verlässlich feststellen, ob ein Arzneistoff „hochlöslich“ gemäß den BCS-Biowaiver Richtlinien der Gesundheitsbehörden FDA, EMA und WHO ist und sich dementsprechend generische Produkte des Arzneistoffs grundsätzlich für das BCS-Biowaiver Zulassungsverfahren eignen.
Dieses Verfahren für die Zulassung von Generika erlaubt die Beurteilung der Bioäquivalenz eines festen generischen Arzneimittels zur peroralen Anwendung auf Basis von in vitro-Freisetzungsuntersuchungen anstatt von in vivo-Studien wie z.B. pharmakokinetischen Studien am Menschen und erleichtert dadurch eine Marktzulassung sowohl durch Zeit- als auch Kosteneinsparung. Die Anwendung des Verfahrens ist von Vorteil, um die Verfügbarkeit von qualitativ hochwertigen, generischen (und damit kostengünstigen) Arzneimitteln zu erhöhen. Dies ist besonders wünschenswert für die Verfügbarkeit von gemäß der Weltgesundheitsorganisation essenziellen Arzneistoffen und unter denen gerade von solchen, die zur Bekämpfung von Krankheiten mit nur wenigen und/oder teuren therapeutischen Alternativen benötigt werden.
Entstanden ist die Löslichkeitsbestimmungsmethode im Rahmen von zwei Projekten, die beide zu diesem Ziel einer guten globalen Gesundheitsversorgung beitragen: die Erstellung der Biowaiver Monografien von Proguanilhydrochlorid (ein Malaria-Prophylaktikum) und Cefalexinmonohydrat (ein Antibiotikum aus der Gruppe der Cephalosporine) setzt die Publikationsreihe „Biowaiver Monograph Series“ der FIP Focus Group „Bioclassification/Biowaiver“ fort. Jede Monografie gibt eine umfassende wissenschaftliche Empfehlung zur Eignung eines Wirkstoffs der WHO „Model List of Essential Medicines“ und seiner generischen Produkte für das BCS-Biowaiver Verfahren hinsichtlich aller regulatorisch geforderten Aspekte ab. Proguanilhydrochlorid (BCS Klasse III – „hochlöslich“ und nicht „hoch permeabel“) und Cefalexinmonohydrat (BCS Klasse I – „hochlöslich“ und „hoch permeabel“) sind beide für dieses Zulassungsverfahren geeignet.
Im Zuge des anderen Projektes wurde die Löslichkeit und anschließend die BCS Klasse von Wirkstoffen bestimmt, die der 16. und 17. Version der WHO „Model List of Essential Medicines“ neu hinzugefügt wurden. Neun von 16 untersuchten Wirkstoffen, die in feste, perorale Arzneimittel formuliert werden können, sind im Hinblick auf ihre BCS Klasse für das eine Zulassung per BCS-Biowaiver geeignet. Eine umfangreichere Empfehlung könnte im Rahmen einer Biowaiver Monografie gegeben werden.
Die experimentelle Bestimmung der Löslichkeit über einen pH-Wert-Bereich von 1-6,8 war essenzieller Bestandteil beider Projekte, da Literaturdaten zur Löslichkeit der Wirkstoffe nicht oder nur unvollständig vorlagen. Die entwickelte Methode basiert auf einer im Kleinmaßstab angesetzten „Shake-Flask“-Methode zur Bestimmung der thermodynamischen Löslichkeit, wird jedoch in einem Zeitrahmen von 24 Stunden durchgeführt. Sie nutzt die höchste Dosis der Wirkstoffe als Substanzmenge, um zu bestimmen, ob dieser „hochlöslich“ gemäß den BCS-Biowaiver Richtlinien ist oder nicht. Die Methode bzw. das dazugehörige Studienprotokoll beinhalten Empfehlungen zu den einzelnen Schritten der Durchführung, der Auswahl der Medien und Herausforderungen wie Präzipitation (Fallbeispiel: Proguanilhydrochlorid) und Zersetzungsreaktionen (Fallbeispiel: Cefalexinmonohydrat). Löslichkeitsdaten, die mit dieser Methode erhoben werden, können für eine Zulassung per BCS-Biowaiver bei den Gesundheitsbehörden eingereicht werden, aber auch für ein Vorab-Screening genutzt werden, dass „hochlösliche“ Arzneistoffe aus einer Vielzahl von Substanzen herauszufiltern soll, um nähere Untersuchungen im Rahmen einer Biowaiver Monografie anzuschließen.
Im Rahmen dieser vorliegenden Thesis wurden verschiedene photosensitive Systeme anhand statischer und zeitaufgelöster optischer Spektroskopiemethoden charakterisiert. Das Hauptaugenmerk dieser Arbeit lag in der Entwicklung und Untersuchung neuer Quantenpunkt-basierter Hybridsysteme. Es war möglich die optischen Eigenschaften der Quantenpunkte über Optimierung der Syntheseschritte zu variieren und so auf geplante Projekte anzupassen.
Im Projekt „Quantenpunkte als Zwei-Photonen Antenne“ sollten die hohen Zwei-Photonen Einfangquerschnitte von Quantenpunkten ausgenutzt werden um in Kombination mit einer photolabilen Schutzgruppe, ein Uncaging im NIR-Bereich zu realisieren. Es wurden ZnSe/ZnS Partikel synthetisiert, die eine starke Emission im Bereich der Absorption der Schutzgruppe zeigen. Anhand von zeitaufgelösten transienten Absorptionsexperimenten mit einer Anregungswellenlänge bei 775 nm wurde eine Zwei-Photonen Absorption der Partikel nachgewiesen. Jedoch wurden starke Emissionsbeiträge aus Fallenzuständen und eine geringe Stabilität beobachtet. Die Synthese von CdS/ZnS Quantenpunkten lieferte stabile Partikel mit geringer trap state Emission. Diese Partikel wurden in einem Modellhybridsystem als Energiedonoren eingesetzt. Als Akzeptor wurde der Farbstoff Cumarin343 gewählt. In statischen Absorptions- und Emissionsmessungen, zeitkorrelierten Einzelphotonenmessungen sowie in fs-zeitaufgelösten transiente Absorptionsmessungen konnte ein ultraschneller Energietransfer nach Ein-Photonen Anregung des Hybridsystems beobachtet werden. Über TPiF Messungen wurde die Zwei-Photonen Absorption der Quantenpunkte detektiert. Ein Energietransfer nach Zwei-Photonen Anregung der Quantenpunkte wurde beobachtet. Schließlich wurde ein Hybridsystem aus CdS/ZnS und der photolabilen Schutzgruppe Az-NDBF (Synthese im AK Heckel, Goethe Universität, Frankfurt a. M.) untersucht. Auch in diesem System wurde ein Energietransfer von Quantenpunkt auf die Schutzgruppe nach Ein- und Zwei-Photonen Anregung beobachtet. Anhand von TA Experimenten wurde eine Zeitkonstante von <100 ps für den Energietransfer nach Ein-Photonen Anregung ermittelt. Es konnte anhand der vorgestellten Resultate gezeigt werden, dass sich Quantenpunkte, aufgrund der guten Anpassung ihrer optischen Eigenschaften generell sehr gut als Antennen für organische Verbindungen eigenen.
Des Weiteren wurde ein Hybridsystem aus CdSe/ZnS Quantenpunkten und einer Dyade (Verbindung eines DTE Photoschalters und BODIPY Derivats), entworfen und charakterisiert. Ein ultraschneller EET von BODIPY auf den geschlossenen DTE Schalter wurde in vorangegangenen Studien beobachtet. Dieser EET führte zur Löschung der BODIPY-Emission. Sobald der Photoschalter im offenen Zustand vorliegt, findet aufgrund des fehlenden spektralen Überlapps kein EET statt und es wird die BODIPY-Emission detektiert. Die Erweiterung der Dyade um einen Quantenpunkt zeigte nach Anregung des Quantenpunkts dessen Fluoreszenzlöschung. Da die Emissionsbande der Quantenpunkte im Absorptionsbereich des BODIPY Farbstoffes liegt, konnte über statische und zeitaufgelöste Experimente ein ultraschneller EET von CdS/ZnS auf den Farbstoff ermittelt werden. Dies führte zu der Erweiterung des Anregungsspektrums des BODIPY Farbstoffs. Die Kopplung der Dyade an die Quantenpunktoberfläche lieferte eine Verbindung mit dem breiten Anregungsspekrum des Quantenpunkts und der schaltbaren Fluoreszenz der Dyade.
Das Hybridsystem aus CdSe Quantenpunkten und PDI zeigte vom Verhältnis der Quantenpunkte zu gekoppelten PDI Molekülen abhängige Fluoreszenzsignale. In TA Experimenten wurde ein ultraschneller EET ermittelt. Für hohe PDI Konzentrationen wurde ein weiterer EET von höher angeregten Elektronen auf das PDI identifiziert. Neben der EET Charakterisierung konnte ein zusätzlicher Prozess innerhalb des Hybridsystems mit hoher PDI Konzentration beobachtet werden. Auf den EET von Quantenpunkt auf PDI folgt ein ET aus dem Valenzband des Quantenpunkts in das HOMO des PDI*. In vorangegangene Arbeiten zu Hybridsystemen aus CdSe/ZnS und PDI wurde kein ET beobachtet. In dem beschriebenen Projekt konnte der Einfluss einer passivierenden Schale auf die elektronischen Eigenschaften von CdSe Quantenpunkten gezeigt werden.
Im letzten Teil dieser Thesis wurde die spektroskopische Charakterisierung einer NVOC und zweier NDBF Schutzgruppen beschrieben. Es konnten anhand statischer Absorptionsmessungen eine Freisetzungsquantenausbeute für NVOC-Adenin von 1,1 % ermittelt werden. Die Charakterisierung der Schutzgruppen mit einer NDBF Grundstruktur (DMA-NDBF und Az-NDBF) ergab eine Abhängigkeit der Freisetzungs- und Fluoreszenzausbeute von der Polarität des Lösungsmittels. In polarer Umgebung reduzierten sich die Quantenausbeuten deutlich...
The most versatile tool for visualizing endogenous RNA is molecular beacons (MBs). MBs are modified oligonucleotides that consist of a stem-loop structure equipped with a fluorophore and a quencher at the opposite ends. They only give a fluorescent signal when hybridized to the target RNA. Here we present our recent efforts to enhance the spatiotemporal resolution of RNA visualization by refining MBs.
We first asked if we could refine MBs to visualize defined subcellular populations of RNA in living neurons. To achieve this, we utilize visible light-activatable Q-dye MBs to allow only a subcellular fraction to be activated. Here, the fluorophore at the 5’-end was linked to a second quencher via a photolabile coumarin protecting group. Therefore, the MB only gives a fluorescent signal, when activated with visible light and hybridized to the target. This architecture allowed local activation of a hybridized subpopulation in a defined area of the cell. Knowing the exact origin of the activated RNA, we were able to increase the available monitoring time for neuronal mRNA from several minutes (literature known MBs) to more than 14 hours.
We next asked if it would be possible to gain spatiotemporal control over where the MB hybridization events occur. Therefore, we developed photo-tethered MBs where two phosphates in the loop backbone are covalently linked to each other via two photocages. This prevents the MB from hybridization to the target RNA. Only when light is applied, the photo-tethers are cleaved, and the inherent hybridization function of the MB is activated. This architecture allowed us to control the hybridization of photo-tethered MBs in primary cultured neurons.
To this day, stroke is the leading cause of death and disability worldwide. Due to increasing age of the world population and poor lifestyle, the incidence is further rising. Besides mechanical thrombectomy as a surgical option, there is a lack of therapeutic options with recombinant tissue plasminogen activator (rt-PA) being the only approved drug for treatment for ischemic stroke. However, there are various problems that make the administration of rt-PA difficult. In particular, it can only be given for ischemic (not hemorrhagic) stroke, and there is a narrow time frame of 4.5 hours after onset of stroke, in which it can be successfully applied. While the success rates of combined thrombectomy with rt-PA are around 60%, less than 5% of patients receive this therapy.
ß-Hydroxybutyrate (BHB) is a ketone body that is formed in high amounts during fasting and lipolysis. Ketone bodes and the ketogenic diet have been shown to have neuroprotective properties in neurodegenerative diseases. In prior work of our group, the ketogenic diet was shown to have beneficial effects in mice after transient ischemia. In the present work, a single dose of BHB was tested for beneficial effects. For this purpose, microdialysis was used to demonstrate that BHB can cross the blood-brain barrier. For the next series of experiments, transient cerebral ischemia was induced in mice for 90 minutes by unilaterally occluding the middle cerebral artery (MCAO) with a silicone-covered filament. Behavioral tests one day after BHB administration showed that the moderate dose of 30 mg/kg, given immediately after reperfusion, improved the neurological score significantly whereas a lower (10 mg/kg) and a higher dose (100 mg/kg) had no effects The main part of the experiments focused on mitochondrial respiration as a potential mechanism of action for BHB. In isolated mitochondria from mouse brain, BHB (1-10 mM) was able to stimulate mitochondrial respiration stronger than pyruvate, but not as strong as succinate.. In the following experiments, MCAO was induced in vivo, and mitochondria were isolated and investigated ex vivo. Experiments were conducted 60 minutes, 24 hours, 72 hours, and 7 days after cerebral ischemia and reperfusion. Besides mitochondrial respiration (normalized to mitochondrial protein content or citrate synthase activity), several other parameters were monitored: the development of bodyweight throughout the experiment, citrate synthase activity, plasma metabolites and behavior to assess motor functions. Three behavioral tests were conducted: first, the Corner test, an experiment for measuring the extent of unilateral movement. Here, if a stroked mouse is put into a narrow corner (30°), it is most likely to turn unilaterally to the right, whereas an unimpaired mouse will turn to both sides randomly. From a total of 10 turns, a laterality index was calculated. Second, in the Chimney test, the mouse walks heads first into a tube. Once it reaches the end, the tube is tipped 90 degrees to stand on the table vertically. Motorically impaired animals have difficulties crawling backwards up to the top of the tube. The experiment was stopped if an animal did not reach the top of the tube within 60 seconds. Third, in the Rotarod test, the mouse is placed on a rotating beam on which it is supposed to walk for at least 60 seconds, and the time when the animal falls off the rotating tube is measured.
All animals that had undergone ischemia showed massive weight loss until 72 hours after reperfusion. Weight loss then stagnated and there was a trend of increasing weight 7 days after reperfusion. The behavioral analysis showed that 24 hours after reperfusion, BHB-treated animals performed significantly better in the Corner test, meaning their moving patterns were more heterogeneous than those of saline-treated animals and in the Chimney test. 72 hours after reperfusion, BHB-treated animals still performed significantly better in the Chimney test, but 7 days after reperfusion, the performances of BHB- and saline-treated animals were no longer different from each other in any of the behavioral tests. In separate experiments, the plasma metabolites glucose, lactate, and pyruvate were changed in the animals that had undergone ischemia but were not affected by BHB administration.
Mitochondrial respiration was tested at four time points after the administration of BHB after reperfusion – 60 minutes, 24 hours, 72 hours, and 7 days after transient cerebral ischemia. 60 minutes later, data showed an increase of oxygen consumption of the complexes I and II. OxPhos was also increased but the effect at this point, did not reach statistical significance. 24 hours after reperfusion, this effect was consolidated: complex I, complex II and OxPhos respiration were significantly improved in the BHB-treated group compared to saline...
Intrinsische und extrinsische Faktoren wie die Darreichungsform, Komedikation und genetische Polymorphismen können einen signifikanten Einfluss auf die Exposition des Wirkstoffes haben und in der Folge zu Veränderungen in der Wirksamkeit oder Sicherheit eines Wirkstoffes führen. Die Fähigkeit die Auswirkungen solcher Faktoren auf die Exposition und die pharmakologische Aktivität eines Wirkstoffes zu quantifizieren und zu extrapolieren, repräsentiert einen Meilenstein bei der Bestimmung der erforderlichen Dosisanpassungen und der Umsetzung von Risikomanagementstrategien in der klinischen Pharmakologie. Unter dem Blickwinkel der modellbasierten Arzneimittelforschung und -entwicklung (engl. model-informed drug discovery and development (MID3)) können dynamisch mechanistische Modelle, wie z. B. whole-body PBPK/PD-Modelle, für die Vorhersage des Effekts sowie der Wechselwirkung mehrerer Faktoren auf PK und PD nützlich sein und könnten daher als Orientierung für die Wahl der Formulierung und für klinische Dosierungsempfehlungen dienen.
Obwohl PBPK-Modelle in der Pharmabranche inzwischen routinemäßig zur internen Entscheidungsfindung und zur Unterstützung der regulatorischen Bewertung eingesetzt werden, bleibt das Vertrauen Waiver von speziellen klinischen pharmakologischen Studien für biopharmazeutische Anwendungen durch PBPK- Modellanalysen zu stützen eher gering. Andererseits hat sich die virtuelle Bioäquivalenz im Zusammenhang mit der Simulation klinischer Studien als ein vielversprechendes, aber noch unterentwickeltes Feld erwiesen, mit dessen Hilfe der Anwendungsbereich der PBPK-Modellierung in der Biopharmazeutik erweitert werden kann. So werden beispielsweise BCS-basierte Biowaiver für Wirkstoffe der BCS-Klassen II und IV derzeit von den Gesundheitsbehörden nicht akzeptiert. In einigen Fällen hat die PBPK-Modellierung durch Verknüpfung der In-vitro-Freisetzung mit der In-vivo-Performance der Formulierung jedoch gezeigt, dass ein solcher Ansatz unter Umständen wissenschaftlich gerechtfertigt sein könnte. Auf ähnliche Weise können PBPK-Modellierung und VBE verwendet werden, um klinisch relevante Spezifikationen für die Wirkstofffreisetzung festzulegen und den "safe space" der Freisetzung zu definieren (oder zu erweitern). Doch selbst bei Wirkstoffen, die Unterschiede im Umfang und in der Rate der Absorption außerhalb der Bioäquivalenzgrenzen aufweisen, was bedeutet, dass sie nicht als bioäquivalent und damit austauschbar angesehen werden können, kann die therapeutische Äquivalenz beibehalten werden, sofern dies durch eine Expositions-Wirkungs-Analyse und/oder eine Expositions-Sicherheits-Analyse unter Verwendung empirischer, halb- oder vollmechanistischer PK/PD-Modelle angemessen begründet wird.
Wie bereits erwähnt bieten PK/PD- und insbesondere PBPK/PD-Modelle einen mechanistischen Ansatz, der die Gewebekonzentrationen am Wirkort des Wirkstoffes mit der pharmakologischen Wirkung verknüpft. Im Rahmen dieser Arbeit wird zunächst ein Überblick über bestehende PK/PD-Modelle und deren mathematischen Umsetzung vorgestellt. Darüber hinaus sind wirkstoffspezifische Fallbeispiele mit einer offensichtlichen Entkopplung von PK und PD von besonderem Interesse, bei denen Expositionsschwankungen weniger kritisch, wenn nicht gar irrelevant für die pharmakologische Reaktion sind (Publikation 1).
In diesem Zusammenhang bietet PBPK Modellierung und Simulation die Möglichkeit die oben genannten wissenschaftlichen Überlegungen zu untersuchen, ungetestete Szenarios zu erforschen und schließlich evidenzbasiert und arzneimittelspezifische Empfehlungen für Bioäquivalenzprüfungen zu erteilen. Daher bestand das Hauptziel darin PBPK/PD-Modelle zu entwicklen, zu validieren und anzuwenden sowie virtuelle Trials zu simulieren, um den relativen Effekt der In-vitro/ In-vivo-Freisetzung, PK-Charakteristiken (z.b. die Halbwertszeit) und die intraindividuelle Variabilität bei der In-vivo-Arnzeimittelwirkung von BCS Klasse II schwach sauren Verbindungen zu beurteilen und einen PBPK-IVIVE integrierten Arbeitsablauf vorzuschlagen, um virtuelle Bioäquivalenzstudien durchzuführen.
Es wurden drei BCS Klasse II schwach saure Wirkstoffe (Naproxen, Flurbiprofen, Ibuprofen) mit ähnlicher Disposition und ähnlichen metabolischen Eigenschaften zur Untersuchung ausgewählt. Allgemein sind alle drei Wirkstoffe stark an Plasmaproteine gebunden und haben daher ein niedriges Verteilungsvolumen, niedrigen First-Pass-Effekt, niedrige systemische Clearance und eine nahezu vollständige Bioverfügbarkeit (F>0.9). Allerdings unterscheiden sie sich signifikant in ihrer Halbwertszeit: Für Naproxen beträgt t1/2≃20-24 h, für Flurbiprofen t1/2≃7 h und für Ibuprofen t1/2≃2 h, was moderate bis lange, moderate und kurze Halbwertszeiten widerspiegelt.
Für alle drei Wirkstoffe wurde ein systematischer Arbeitsablauf erstellt einschließlich: i) Charakterisierung von in vitro biopharmazeutischen Eigenschaften (z.b. Löslichkeit, Freisetzung) gefolgt von modellbasierten Analysen von In-vitro-Ergebnissen, ii) Entwicklung und umfassende Validierung von PBPK/PD-Modellen und iii) Simulierung und Risikoeinschätzung von Bioäquivalenzstudien. Die Fallstudien von Naproxen (Publikation 2) und Ibuprofen (Publikation 3) konzentrieren sich auf bewährte Verfahren der IVIVE für biopharmazeutische Parameter, Risikoabschätzung und Simulation von Bioäquivalenzstudien mit PBPK-Modellen, welche die inter-occasion Variabilität miteinbeziehen. Das Beispiel von Flurbiprofen (Publikation 4) hebt die Wichtigkeit des Verständnisses des relativen Einflusses von intrinsischen (z.b. genetische Polymorphismen) und extrinsischen (z.b. Komedikationen) Faktoren auf die PK und PD des Wirkstoffes hervor, wenn Empfehlungen für die Bioäquivalenz und die therapeutische Gleichwertigkeit gemacht werden. Alle drei Fallbeispiele liefern mechanistische Erkenntnisse über die Freisetzungssgrenzen, die für die In-vivo-Arneimittelwirksamkeit kritisch ist, unter Berücksichtigung der PK-Eigenschaften des Wirkstoffes und der physiologischen Variabilität mit dem Ziel den Status quo des aktuellen BCS-basierten Biowaiveransatzes in Frage zu stellen und integrierte In-vitro-, In-vivo- und In-silico-Paradigma der Risikobewertung für Waiver von In-vivo-Bioäquivalenzstudien einzuführen.
In dem letzten Teil der Arbeit werden Herausforderungen, Kenntnislücken und Möglichkeiten von PBPK/PD-Modellierung zur Unterstützung von Waivern von in vivo klinischen Studien im Bereich von oralen Biopharmazeutika diskutiert (Publikation 5).
Im Großen und Ganzen schlägt diese Dissertation biorelevante In-vitro-Methoden für die Vorhersage von In-vivo-Formulierungsperformance und neue PBPK/PD-Methoden vor, um Daten von in vitro biopharmazeutischen Experimenten zu den In-vivo-Bedingungen zu extrapolieren. Außerdem ist dies das erste Mal nach unserem Kenntnisstand, dass PBPK/PD-Ansätze zur Durchführung virtueller Bioäquivalenzstudien vorgeschlagen werden, die auch die inter-occasion Variabilität der Pharmakokinetik berücksichtigen. Desweiteren hebt diese Arbeit die Bedeutung von pharmakokinetischen Eigenschaften auf Bioäquivalenz-Ergebnissen hervor und stellt ein neues Konzept zur Risikoeinschätzung von Bioäquivalenz vor, in welchem die Bewertung des Bedarfs eines Waivers von einer In-vivo-Bioäquivalenzstudie sowohl auf biopharmazeutischen als auch pharmakokinetischen Wirkstoffeigenschaften basiert und quantitativ mit PBPK/PD-Modellierung bewertet wird.
Macroautophagy, herein referred to as autophagy, is an evolutionarily conserved homeostatic process that normally occurs inside eukaryotic cells which involves degradation of cytoplasmic substances via lysosomes. It can be induced by various conditions such as starvation and drug exposure, as well as be inhibited by numerous compounds. Under normal conditions, the doublemembrane autophagosomes engulf the cytosolic substrates and deliver them to lysosomes for digestion. These substrates include unnecessary or dysfunctional cell components, such as faulty macromolecules, organelles and even invading pathogens. Autophagosomes are formed through the co-operative work of various autophagy-related (ATG) proteins organized into complexes. Upon closure of the autophagosomes, they fuse with the acidic lysosomes, resulting in formation of autolysosomes and the delivery of lysosomal hydrolases to degrade the engulfed contents. The fusion of the autophagosome with lysosome is carried out by specific SNARE proteins, small GTPases and their effectors including tethers, adaptors and motor proteins. Autophagy is impaired in many human diseases including cancer, neurodegenerative diseases, aging and inflammation. Therefore, manipulation of autophagy pathway holds a great promise for new therapeutic applications ...
Zika-virus (ZIKV), a flavivirus mainly transmitted by Aedes mosquitoes, is a single-stranded, positive-sense RNA virus. The viral genome is surrounded by a nucleocapsid and a lipid bilayer, in which membrane and envelope proteins are embedded. ZIKV disease is mainly characterized by mild symptoms, such as fever, rash as well as pain in head and joints. However, after epidemics it caused in the Americas in 2015/16, ZIKV infections were also associated with severe neurological complications like the Guillain-Barré syndrome (GBS) and microcephaly in fetuses and newborns. So far there are no specific antiviral treatments or vaccines available against ZIKV. This strengthens the need for a detailed understanding of the viral life cycle and virus-host interactions.
The antiviral host factor tetherin (THN) is an interferon-stimulated protein and therefore part of the cellular innate immune response. It comprises an N-terminal cytoplasmic domain, followed by a transmembrane helix, an extracellular coiled-coil domain and a C-terminal glycosylphosphatidylinositol (GPI) anchor. Containing two sites for membrane insertion linked by a flexible structure, THN is able to integrate into the membrane of budding viruses, thereby attaching them to each other and to the cell membrane and preventing their further release and spread.
In this study, the crosstalk of ZIKV and THN was analyzed. Previous gene expression analyses by microarray and quantitative polymerase chain reaction (qPCR) had revealed a strong upregulation of the BST2 gene encoding for THN in ZIKV-infected cells. However, this enhanced expression did not correlate with an enhanced THN protein level. On the contrary, the amount of THN in THN-overexpressing cells was after infection even heavily reduced. Furthermore, immunofluorescence analyses revealed a loss of THN membrane localization in these cells. By performing a cycloheximide assay, this loss could be traced back to a reduced protein half-life of THN in infected versus uninfected cells. Treatment with inhibitors of different protein degradation pathways as well as colocalization analyses with markers of several subcellular compartments indicated an involvement of the endo-lysosomal route. A knock-down of the ESCRT-0 protein HRS however prevented the sorting of THN for lysosomal degradation and led to a stabilization of THN protein levels. After HRS depletion, the release and spread of viral particles was reduced in THN-overexpressing compared to wildtype cells.
Taken together, the data obtained in this study revealed the potential of THN to restrict ZIKV release and spread. The enhanced degradation of THN in ZIKV-infected cells via the endo-lysosomal pathway could therefore be explained as an effective viral escape strategy. This could be circumvented by knockdown of the ESCRT-0 protein HRS, which highlighted HRS as a potential target for the development of antiviral treatments.
Pulsed dipolar (PD) EPR spectroscopy is an established and reliable tool for the investigation of biomolecules. In terms of long distance and orientation measurements, it is one of the leading methods and further fields of application are constantly being explored. The distances that can be detected with PD EPR also correspond to the range in which almost all important biomolecule interactions occur. In the transition from in vitro spectroscopy to in-cell spectroscopy, the power of PD EPR spectroscopy is particularly evident. It is non-invasive, more sensitive than NMR, and does not exhibit background signals from diamagnetic molecules. In particular, the absence of background signals is of great importance given the high density of molecules within cellular environment. However, like any other spectroscopic method, PD EPR has certain limitations. Owing to the intrinsically fast electron spin echo dephasing at higher temperature, these experiments are commonly carried out in frozen solutions at about 50 K. This temperature is far away from the physiological conditions and the freezing additives used, e.g. glycols, can further influence the structure. To enable measurements with and within living organisms, it is therefore necessary to ascend from the cold depths of the frozen state. At the same time, one has to adapt the spin tags for the desired application. Established nitroxides commonly used for EPR studies are typically susceptible to reduction. Thus, for studies under physiological conditions, e.g. in the cell, one has to fight against the reductive environment in the cell and somehow protect the spin labels. Initial published in-cell experiments within the research group and investigations of homogeneously distributed labeled double-stranded (ds) ‐DNA samples in solid matrices showed promising results and enabled pulsed measurement in the temperature range of 50‐ 295 K. It could also be demonstrated that spherical shielded nitroxides have a significantly longer life span in cellular environments than non-protected ones and first nuclear acids were measured in cell. Based on these results, we have gone further to overcome the standing limitations and developed the use of PD EPR spectroscopy. This work addresses these challenges with the overall goal of advancing the applications of PD EPR spectroscopy for studying biomolecules under physiological conditions.
We have focused on four different approaches. The results of these studies were published in various publications. They are presented and discussed together with further studies and put into the context of research conducted before and after the authors' publications.
In approach 1, we fought against the two main obstacles for using pulsed dipolar spectroscopy at ambient conditions – minimizing phase memory time T2 and averaging of the anisotropic dipolar coupling by rotational diffusion. We focused on an immobilization approach, while using rigid spin labels at same time. Besidesto the distance information, the incorporated rigid spin labels will give additional angular constrains and information about the molecular dynamics.
In approach 2, we focused on the on-site and on-demand formation of nitroxide spin labels using light-sensitive alkyl protection groups. This a very mild and efficient procedure that will hardly interfere with sensitive functional groups present in oligonucleotides or peptides. By establishing this method and using coumarin protecting groups plus two-photon excitation, this property may offer the potential to generate spin labels with very high levels of spatial and temporal resolution.
For approach 3, we used paramagnetic Gd3+ -ions as intrinsically stable labels, which are not reducible within a cellular environment. Easy to mix and bound to encodable lanthanide binding tags within the molecule Interleucin 1β, we were able to measure distances between two tags with PELDOR spectroscopy. We tested the extent to which this system is suitable for in-cell measurements.
Finally, we focus on methods for easier labeling by using non-covalentlabeling techniques. One of these is the novel nitroxide G´ for site-directed spin labeling of nucleic acids, especially for RNA. This spin label is sterically hindered, easy to build and binding occurs in seconds by simply mixing the spin label with the target. For large RNAs, another easy-to-mix and noncovalent spin-labeling strategy will be experimentally accompanied and presented.
The approaches and results described here are intended to demonstrate that the study of the biological functions of biomolecules under physiological conditions by pulsed EPR spectroscopy is feasible and operational. In combination, they will enable the life sciences to make further and faster progress in the search for the molecular master plan.
Rhabdomyosarcoma (RMS) is the most common soft tissue sarcoma in early childhood. Despite recent advances in the treatment regimes of rhabdomyosarcoma, the 5-year survival is still alarmingly low for the more aggressive metastasizing alveolar rhabdomyosarcoma subtype. Novel treatment strategies are needed in order to increase the overall survival rate. Hallmarks of cancer include evade cell death induction and evade immune system surveillance. This is mediated in part by up-regulation of inhibitor of apoptosis (IAP) proteins. With the development of Smac mimetic compounds mimicking the endogenous IAP antagonist Smac, this tumor evasion mechanism became exploitable.
In this PhD thesis, a combinatory approach for a putative treatment option of RMS will be presented. Here, the Smac mimetic compound BV6 will be used as a pre-treatment of RMS cells. This leads to a sensitizing effect within the tumor cells, increasing the killing efficacy of natural killer (NK) cells.
Subtoxic concentrations of BV6 were chosen to sensitize RMS cells. To remodel the solid tumor characteristics of RMS, a multicellular RMS tumor spheroid culture model was used.
In both tumor spheroids and conventional monolayer cell culture BV6 induced the degradation of IAP proteins (cIAP1, cIAP2, in spheroids XIAP). Further, BV6 led to the activation of both, the canonical and non-canonical NF-κB signaling pathways.
This was demonstrated by an increased IκBα and p65 phosphorylation, and nuclear translocation of p-p65, indicative for an active canonical NF-κB signaling. On the other side, cIAP degradation led to the stabilization and accumulation of NIK and downstream partial degradation of p100 to p52 and its nuclear translocation, indicating non-canonical NF-κB signaling pathway activity. A bulk RNA sequencing approach of BV6 treated RH30 cells validated the NF-κB signaling involvement and identified 182 differentially expressed genes. Among the interesting target genes are NFKBIA (IκBα),BIRC3 (cIAP2), NFKB2 (p100), CCL5 and SSTR2. SSTR2 was thoroughly validated as being up-regulated on a transcriptional and on protein level. Here, SSTR2A, one of the two alternative splicing variants, is up-regulated and opens a hypothetical targeted treatment strategy, as SSTR2 expression is not associated with RMS, but rather described with neuroendocrine tumor entities. In addition, CCL5 was thoroughly validated as a BV6 induced target. Again, the up-regulated mRNA transcription was validated by an increased translation and by increased secretion of CCL5. As CCL5 being associated as pro-migratory and activating of NK cells, CRISPR/Cas9 mediated CCL5 knock-out studies were performed to evaluate the influence of CCL5 within a BV6 pre-treatment and NK cell co-cultivation setting. It was shown that CCL5 knock-out does not rescue BV6 pre-treated RMS spheroids from NK cell attack and killing.
The previous mentioned transcriptional activity by BV6 stimulation was NIK mediated as knock-down of NIK reduced the mRNA transcription of several interesting genes.
However, NIK mediated down-stream signaling had no influence on the BV6 induced sensitizing effect towards NK cell mediated attack. A NIK knock-down had no rescue effect upon BV6 pre-treatment and NK cell co-treatment.
As cIAP proteins are present in receptor bound complexes, e.g. complex I at the TNF receptor 1 (TNFR1), a putative involvement of death receptors in general was evaluated.
Indeed, BV6 treatment of RMS cells could increase the surface presentation of DR5, a death receptor ligating TRAIL. Functionally, co-treatment of BV6 with TRAIL led to an additive cell death inducting effect. However, within the NK cell co-cultivation setting, addition of a neutralizing TRAIL anitbody could not rescue BV6 pre-treated RMS spheroids from NK cell killing. A similar effect was observed when neutralizing TNFα by adding Enbrel during the NK cell co-cultivation. BV6 sensitization of RMS spheroids seems to be independent of death receptors.
In addition to activating NF-κB, BV6 as a Smac mimetic is supposed to be able to release caspases bound by IAP proteins. Indeed, BV6 pre-treatment of RMS spheroids and co-cultivation with NK cells could cleave and thereby activate the executioner caspase-3. Further, treatment with a pan-caspase inhibitor, zVAD.fmk, could reduce the BV6 mediated sensitizing effect towards NK cell attack in RD spheroids.
Taken together, BV6 does induce a thoroughly validated NF-κB signaling pathway, leading to a NIK mediated transcriptional signature change. However, the NF-κB activation might not be responsible for the observed sensitization. Further, BV6 in combination with NK cells led to a seemingly death receptor independent, caspase dependent cell death induction of RMS spheroids. Although the mechanism remains partially con-cealed, a therapeutic benefit by combining a cell death sensitizing compound, i.e. BV6, with cytotoxic lymphocytes is evident.
KMT2A-rearrangements are causative for 70-80% all infant acute lymphoblastic leukemias (Pieters et al., 2019, 2007). Among these, the translocation t(4;11)(q21;23) generating the oncogenic fusion genes KMT2A::AFF1 and AFF1::KMT2A is the most frequent one, accounting for almost every second case of KMT2A-r infant ALL (Meyer et al., 2018). Despite passing a multimodal chemotherapy, 64% of patients achieve an event including relapse or death within four years from diagnosis, and overall survival three years from relapse remains poor with only 17% (Driessen et al., 2016; Pieters et al., 2019, 2007). Vari-ous studies have shown that relapse and therapy resistance were not mediated by chemotherapy-induced mutagenesis as there was no accumulation of secondary mutations in the dominant leukemic clone between diagnosis and relapse (Agraz-Doblas et al., 2019; Andersson et al., 2015; Bardini et al., 2011; Dobbins et al., 2013; Driessen et al., 2013; Mullighan et al., 2007).
Intriguingly, exclusively infant t(4;11) ALL patients were reported to subdivide in two groups depending on the level of HOXA gene cluster expression (Trentin et al., 2009). The HOXAlo group displayed a high expression of IRX1 and the HOXAhi group a low expression of IRX1 (Symeonidou and Ottersbach, 2021; Trentin et al., 2009). Importantly, the HOXAlo/IRX1hi group was characterized to possess a strongly ele-vated relapse incidence compared to the HOXAhi/IRX1lo group (Kang et al., 2012; Stam et al., 2010). IRX1 was identified to upregulate the Early growth response genes EGR1, EGR2 and EGR3 (Kühn et al., 2016).
The doctoral project “EGR-mediated relapse mechanisms in infant t(4;11) acute lymphoblastic leuke-mia” aimed to investigate a potential correlation between the HOXAlo-IRX1-EGR axis and relapse development in infant t(4;11) ALL. The primary objective was to clarify through which molecular mechanism(s) relapse development despite continuous chemotherapy could be achieved. In this context, the role of the EGR genes has been investigated. In addition, this project aimed to disclose molecular targets which could offer novel therapeutic interventions to interfere with therapy resistance and relapse formation.
Meat adulteration is a global problem which undermines market fairness and harms people with allergies or certain religious beliefs. In this study, a novel framework in which a one-dimensional convolutional neural network (1DCNN) serves as a backbone and a random forest regressor (RFR) serves as a regressor, named 1DCNN-RFR, is proposed for the quantitative detection of beef adulterated with pork using electronic nose (E-nose) data. The 1DCNN backbone extracted a sufficient number of features from a multichannel input matrix converted from the raw E-nose data. The RFR improved the regression performance due to its strong prediction ability. The effectiveness of the 1DCNN-RFR framework was verified by comparing it with four other models (support vector regression model (SVR), RFR, backpropagation neural network (BPNN), and 1DCNN). The proposed 1DCNN-RFR framework performed best in the quantitative detection of beef adulterated with pork. This study indicated that the proposed 1DCNN-RFR framework could be used as an effective tool for the quantitative detection of meat adulteration.
The current pandemic situation caused by the Betacoronavirus SARS-CoV-2 (SCoV2) highlights the need for coordinated research to combat COVID-19. A particularly important aspect is the development of medication. In addition to viral proteins, structured RNA elements represent a potent alternative as drug targets. The search for drugs that target RNA requires their high-resolution structural characterization. Using nuclear magnetic resonance (NMR) spectroscopy, a worldwide consortium of NMR researchers aims to characterize potential RNA drug targets of SCoV2. Here, we report the characterization of 15 conserved RNA elements located at the 5′ end, the ribosomal frameshift segment and the 3′-untranslated region (3′-UTR) of the SCoV2 genome, their large-scale production and NMR-based secondary structure determination. The NMR data are corroborated with secondary structure probing by DMS footprinting experiments. The close agreement of NMR secondary structure determination of isolated RNA elements with DMS footprinting and NMR performed on larger RNA regions shows that the secondary structure elements fold independently. The NMR data reported here provide the basis for NMR investigations of RNA function, RNA interactions with viral and host proteins and screening campaigns to identify potential RNA binders for pharmaceutical intervention.
Leukemia is a cancer of the blood and bone marrow characterized by an uncontrolled proliferation and accumulation of abnormal white blood cells. Leukemia can be classified based on the course of the disease (acute or chronic) and the blood cell type involved (myeloid or lymphocytic), leading to four main subtypes: acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL) and chronic myeloid leukemia (CML). Leukemia represents 2.5% of all new cancer cases per year, and survival rates in some leukemias remain low at 40%.
The bone marrow microenvironment (BMM) is a system within the bone marrow comprising cellular and acellular components, all of which play a major role in hematopoiesis, providing the physical space where hematopoietic stem cells (HSCs) reside. The BMM interacts with HSCs, offering a “niche” for those cells and in case of leukemia, the BMM has a supportive role in disease maintenance and progression by supporting Leukemia stem cells (LSCs). One of the components of the BMM are calcium ions. Calcium is the most abundant mineral in the body, a key component of bones and is released by parathyroid hormone (PTH) induced bone remodeling. Calcium ions play a role in the localization, engraftment and adhesion of normal HSC to extracellular matrix (ECM) proteins in the BMM via the calcium sensing receptor (CaSR), thereby maintaining normal hematopoiesis. In addition of a major regulator of calcium homeostasis, CaSR contribute to the development of different cancers, functioning as either tumor suppressor or oncogene, depending on the involved tissue. However, the role of CaSR and its associated pathways in the local BMM for the development of leukemia is poorly understood. We hypothesized that calcium ions released from bone, subject to a fine balance between osteoblasts and osteoclasts, and/or CaSR, contribute to development, progression and response to therapy.
We have shown that the local calcium concentration forms a gradient in the bone marrow niche and in mice with CML is similarly low as in control mice, but significantly higher in mice suffering from BCR ABL1 driven B ALL or MLL AF9 driven AML. Similarly, the calcium concentration in the human BMM was found to be higher in AML than in other leukemias. Regarding the function of calcium in leukemia cells, we found that AML and CML cells respond differently to calcium exposure, with AML cells exhibiting regulation of cellular processes such as adhesion to the ECM protein fibronectin and migration toward CXCL 12, whereas CML cells remained mostly unaltered. Using genetic deletion or overexpression of CaSR in murine models of leukemia, we observed that CaSR acts as tumor suppressor in BCR-ABL1 driven CML and B ALL and as oncogene in AML.
Focusing on AML, our data shows that deficiency of CaSR on LICs leads, on one hand to increased apoptosis, and on the other hand to reduced cell cycle, reactive oxygen species (ROS) production and DNA damage in vivo, which may explain the observed prolongation of survival of mice. Complementary, in vitro experiments demonstrated that cells overexpressing CaSR have a distinct, cancer promoting phenotype compared to wildtype cells. Overexpression of CaSR led to an increase in proliferation, cell cycle, ROS production, DNA damage and reduced apoptosis. We have identified CaSR mediated pathways in AML and shown that CaSR enhances leukemia progression by activating MAPK/ERK and Wnt β catenin signaling. In addition, the CaSR interacting protein filamin A (FLNA) was shown to contribute to aggressive disease in vitro and in vivo. Furthermore, the mechanism underlying the role of CaSR in AML pathogenesis and possible regulation of LSCs was studied. Our findings demonstrated that CaSR ablation reduces myeloid progenitor function and proved that CaSR is required for maintenance of LSC pool by regulating its frequency and function. Further supporting the role of CaSR in LSC maintenance, genes associated with AML stemness and self renewal capacity were upregulated when CaSR was overexpressed and downregulated when CaSR was depleted. Given the role of CaSR in AML, the CaSR antagonist NPS 2143 was tested in vivo. The combination treatment of NPS 2143 with the standard of care, ara C, significantly reduced the tumor burden and prolonged the survival of mice with AML in syngeneic and xenotransplantation experiments. Based on the finding that CaSR functions as a tumor suppressor in CML, treatment of mice with the CaSR agonist cinacalcet in combination with imatinib prolonged survival of mice with CML compared to treatment with the mice given vehicle.
Our results suggest that calcium ions stemming from the calcium-rich BMM via CaSR strongly and differentially influence leukemia progression. As an adjunct to existing treatment therapies, targeting of CaSR with specific pharmacologic antagonists may prolong survival of patients with AML.
In dieser Arbeit konnte 1,8-Diborylnaphthalin (11) präparativ in einer Stufe und 65% Ausbeute aus dem literaturbekannten Boronsäureanhydrid 9 dargestellt werden. 11 ist das zweite bekannte, aromatisch verbrückte Derivat des Diborans B2H6. 11 kann als Startverbindung für eine Reihe strukturverwandter BNB-dotierter Phenalenderivate verwendet werden. Dazu werden zwei der vier Bor-gebundenen Protonen durch die Umsetzung mit einem Mesitylgrignard und Trimethylsilylchlorid substituiert. Die Umsetzung mit Wasser bzw. Aminen liefert BOB- bzw. BNB-Phenalene unter Freisetzung von elementarem Wasserstoff. Alle, auf diese Weise dargestellten Verbindungen, zeigen reversible Redoxeigenschaften und Photolumineszenz mit zum Teil besonders scharfen Emissionssignalen mit Halbhöhenbreiten von bis zu 31 nm. Zusätzlich wurden drei analoge Vertreter einer NBN-Phenalen Spezies dargestellt und charakterisiert. Die entgegengesetzte Dotierung äußert sich in einem grundlegend verschiedenem Redoxverhalten. Abschließend wurde die Reduktion des BNB-Phenalens 22 untersucht. Dabei gelang es das Radikal K[32] zu charakterisieren und seine Abbaureaktion in THF aufzuklären.
Biomoleküle, insbesondere Membranproteine (MPs), sind oftmals sehr sensitiv gegenüber ihrer chemischen Umgebung, wie pH-Wert, Puffer, Salzkonzentration und vielen weiteren Faktoren. MPs stabil und funktional in Lösung zu halten ist nicht trivial. Sie stellen deshalb eine besondere Herausforderung bei der Analyse von biologischen Systemen dar. Aus diesem Grund wurden und werden nach wie vor sogenannte membrane mimicking-(MM-) Systeme, wie beispielsweise Nanodiscs (NDs) oder styrene-maleic acid lipid particles (SMALPs), untersucht und entwickelt, um MPs eine naturähnliche Umgebung in Form einer Lipid-Doppelschicht zu bieten und sie so in ihrer natürlichen Konformation und natürlichen Funktionsweise/Aktivität in Lösung zu halten.
Laser induced liquid bead ion desorption (LILBID) Massenspektrometrie (MS) hat sich als hervorragende analytische Methode herausgestellt, um MPs in Kombination mit MM-Systemen zu untersuchen. LILBID-MS bietet nicht nur die Möglichkeit Proteine an sich zu identifizieren, sondern ermöglicht ebenfalls eine zerstörungsfreie Analyse von nicht-kovalent gebundenen Proteinkomplexen, sowie die Detektion einzelner Subkomplexe eines Proteinkomplexes. Auch die Analyse von Protein-Ligand-Wechselwirkungen ist möglich. Bei der LILBID-Ionisationsmethode werden kleine Tröpfchen erzeugt, die einen wässrig gelösten Analyt enthalten. Die Analyt-Tröpfchen werden anschließend mittels IR-Laser bestrahlt, wodurch der Analyt freigesetzt und massenspektrometrisch analysiert werden kann.
Diese Dissertation beschäftigt sich zum einen mit der Analyse des Lyse-Proteins ΦX174-E der Bakteriophage ΦX174, zum anderen mit Untersuchungen zur Histidinkinase SpaK aus B. subtilis in Kombination mit MMs. Weiterhin wird die Frage geklärt, ob und wie gut sich LILBID-MS zur Analyse von Saposin-Nanopartikel-(SapNPs)-solubilisierten MPs eignet. Darüber hinaus wird in dieser Dissertation die Darstellung von SapNP-solubilisierten MPs mittels zellfreier Proteinsynthese näher charakterisiert und untersucht welche Parameter aus präparativer Sicht optimiert werden können.
In vorausgegangenen Analysen von ND-solubilisierten MPs mittels LILBID-MS zeigte sich, dass manche in Verbindung mit NDs genutzten Lipide unerwünschte Signale im Spektrum zur Folge haben, die aus massiven Lipid-Anhaftungen am MSP oder dem Analyten resultieren. Überlappungen der m/z-Signale verschiedener Analyt- und/oder Komplexkomponenten mit diesen Lipid-Cluster-Signalen kann wiederum zum Verlust von Informationen führen. Daher beschäftigt sich ein weiterer Teil dieser Arbeit mit der Frage, ob durch den Einsatz von UV-schaltbaren Lipiden der Anwendungsbereich und/oder die Auflösung von LILBID-MS erweitert und verbessert werden kann.
Um biologische Prozesse zu verstehen ist es ebenfalls wichtig die zeitlichen/kinetischen Aspekte einer Reaktion zu untersuchen/kennen, sowie molekulare Prozesse gezielt zu kontrollieren. Licht hat sich hierbei als ein hervorragendes Werkzeug in der Analytik, sowie in der molekularen Prozesskontrolle etabliert. Licht bietet den Vorteil sehr selektiv eingesetzt werden zu können und sowohl orts- als auch zeitaufgelöst Informationen liefern zu können. Das gezielte Triggern einer Reaktion oder einer Protein-Protein-Interaktion kann beispielsweise durch sog. photo-cleaving von photolabilen Schutzgruppen ermöglicht werden. Bisweilen bietet die native MS nur wenig Möglichkeiten schnelle Reaktionen zu analysieren und kinetische Informationen zu gewinnen. Daher beschäftigt sich ein weiterer Teil dieser Dissertation damit zu untersuchen, ob und wie sich lichtgesteuerte Reaktionen im LILBID-Ionisationsprozess induzieren und gegebenenfalls auch zeitlich analysieren und charakterisieren lassen können.
Oxidative stress is thought to be a driver for several diseases. However, many data to support this concept were obtained by the addition of extracellular H2O2 to cells. This does not reflect the dynamics of intracellular redox modifications. Cells actively control their redox-state, and increased formation of ROS is a response to cellular stress situations such as chronic inflammation.
In this study, it was shown that different types of ROS lead to different metabolic and transcriptomic responses of HUVECs. While 300 μM extracellular H2O2 led to substantial metabolic and transcriptomic changes, the effects of DAO-derived H2O2 and menadione were low to moderate, indicating that the source and the concentration of ROS are important in eliciting changes in metabolism and gene expression.
Specifically, it was identified that acute increases in ROS transiently inactivate the enzyme ω-amidase/NIT2 of the glutaminase II pathway, which supplies cells with anaplerotic α-ketoglutarate. The pathway has not been studied systematically because, as noted above, the major intermediate, KGM, is not commercially available. In the present study, an internal standard for targeted detection of KGM in cells and blood plasma/serum was used. Deletion of NIT2 by CRISPR/Cas9 significantly reduced α-ketoglutarate levels in HUVECs and elevated KGM levels. It appears that in cell culture conditions, hydrolysis of KGM to α-ketoglutarate is very efficient. Knockout of the glutamine transaminases significantly reduced methionine, suggesting that the glutaminase II pathway is an important source of amino acid replenishment.
Similar to genetic silencing of GLS1 [91,92], HUVECs lacking NIT2 showed reduced proliferation and angiogenic sprouting. Furthermore, our results indicate that, at least in HUVECs, the enzyme also locates in the mitochondria where it interacts with key enzymes of glutamine/glutamate/α-ketoglutarate metabolism.
The data of the present work indicate that the glutaminase II pathway is an underappreciated, redox-sensitive pathway for glutamine utilization in HUVECs. Genetic deletion of NIT2 has considerable physiological effects highlighting the importance of glutamine for ECs.
Damit in der Schule die Vermittlung eines adäquaten Energieverständnisses gelingen kann, benötigt es eine Lehrkräfteausbildung, die dessen Herausforderungen in den Blick nimmt und die angehenden (Chemie-) Lehrerinnen und Lehrer aus fachwissenschaftlicher und didaktischer Perspektive vorbereitet. Denn in die Unterrichtsvorbereitung fließen neben bildungspolitischen und curricularen Vorgaben auch die Vorstellungen und Überzeugungen der Lehrkräfte mit ein. Zu den Herausforderungen, mit denen Lernende wie Lehrende konfrontiert sind, zählen die verschiedenen mentalen Repräsentationen zum Wort Energie aus Alltag und Naturwissenschaft, die zahlreichen chemischen Fachkontexte, in denen Energie bzw. Energiephänomene eine Rolle spielen, die unterschiedlichen Wissensnetze, die mit dem Begriff in den verschiedenen Naturwissenschaften verknüpft sind und der Einfluss der Fach- bzw. Alltagssprache.
Die (angehenden) Lehrkräfte fühlen sich auf diese Aufgabe oftmals fachlich nicht ausreichend vorbereitet. Um die Lehrkräfteausbildung in ihrem ersten Ausbildungsabschnitt auf die genannten Herausforderungen anzupassen und Lehrformate zu erweitern, benötigt es umfangreiche Kenntnisse über die mentalen Repräsentationen der Studierenden zur Energie sowie die damit verbundenen alternativen Konzepte zu schulrelevanten und lehrplanorientierten Themenschwerpunkten und die sprachlichen Besonderheiten. Die Vielschichtigkeit des Begriffs Energie erfordert eine ganzheitliche Betrachtung aller Aspekte, die es so bislang nicht gibt.
Aus diesem Grund ist es Ziel dieser Studie, die mentalen Repräsentationen der Studierenden, wie auch deren alternative Konzepte zu ausgewählten energiebezogenen Fachbegriffen aus den Bereichen chemische Bindungen, Thermodynamik und chemische Reaktionen zu erheben, in einen gemeinsamen fachlichen und sprachlichen Kontext zu setzen und daraus Rückschlüsse auf das Energieverständnis zu ziehen.
Im Sinne des Modells der didaktischen Rekonstruktion wird eine fachliche Klärung zum Untersuchungsgegenstand Energie durchgeführt. Für die Erhebung der empirischen Daten findet ein Rückgriff auf halbstandardisierte Leitfadeninterviews statt. Zielgruppe sind angehende Chemielehrkräfte, die mindestens im 5. Fachsemester Chemie für das Lehramt an Gymnasien studierten. Die Auswertung der Interviews erfolgt unter Rückgriff auf die qualitative Inhaltsanalyse nach Mayring und wird mit quantifizierenden Elementen trianguliert.
Die Studie zeigt die Erklärungsvielfalt des Begriffs Energie auf, denen sich die Studierenden bedienen. Dabei werden vor allem Beispiele einzelner Energiephänomene oder Energieformen herangezogen. In den verschiedenen Fachkontexten konnten diverse alternative Konzepte detektiert werden. Darüber hinaus konnten übergreifende Herausforderungen detektiert werden. Erkennen die Studierenden Widersprüche in ihrem Energieverständnis, wird Energie als abstrakt und schwer fassbar beschrieben. Zudem wird eine anthropozentrische Sicht eingenommen. Die angehenden Lehrkräfte neigen zu einer starken Kompartmentalisierung und begründen Wissenslücken mit der Zugehörigkeit zu anderen Fachwissenschaften. Eine weitere wichtige Erkenntnis aus der Studie ist, dass in den Fachwissenschaftlichen Veranstaltung die qualitativen Diskussionen angeregt werden müssen. Die zukünftigen Lehrerinnen und Lehrer bewegen sich in einem Spannungsverhältnis zwischen Fachwissenschaft und Didaktik und sind sich dessen sehr deutlich bewusst, indem sie bei Begriffsdefinitionen und Erklärungen die Anschaulichkeit der Exaktheit vorziehen. Es besteht die Notwendigkeit, Fachbegriffe in einem größeren Zusammenhang zu erläutern und die Studierenden zur Kommunikation darüber anzuregen.
This work deals with the theoretical investigation of the vibrationally promoted electronic resonance (VIPER) experiment, the intramolecular energy transfer within a rhodamine-BODIPY antenna system initiated by two-photon excitation and a computational study of the photochemical mechanism of the uncaging of the [7-(dimethylamino)coumarin-4-yl]methyl (DEACM) class of photocages . In continuation to Jan von Cosel’s work, the setup for the theoretical investigation of the VIPER experiment has been extended to two-photon absorption (TPA) also including the first-order Herzberg-Teller (HT) effects which are dependent on changes with respect to nuclear coordinates.
The VIPER experiment constitutes an extended form of two-dimensional infrared (2DIR) spectroscopy with a sequence of infrared (IR) and ultraviolet (UV) or visible (vis) pulses. The molecular system under probe is excited initially by a narrow-band IR pump pulse and then electronically excited by an off-resonant UV/vis pulse. An IR probe pulse is applied afterwards to probe the system and record a 2DIR spectrum in combination with the first pulse. Since the lifetime of the vibrational excitation is very short, the electronic excitation by the UV/vis pulse is used to enlarge the lifetime of the excitation in the molecule and thus enable measurements on a longer timescale. Therefore, it becomes easier to study dynamical photochemical processes on long timescales. In the VIPER experiment with TPA, the UV/vis pulse is replaced by a near-infrared (NIR) pulse which offers an intrinsic 3D resolution, minimzed photodamage, a lower noise level and an increased penetration depth. This makes TPA highly attractive for biological systems among a wide range of other possible applications.
The computation of the vibrationally resolved electronic absorption spectra accounts for the Franck-Condon (FC) contributions which are independent of the nuclear framework as well as the HT effects which are dependent on the nuclear coordinates. The FC contributions are dominant for electronically-allowed transitions whereas HT contributions could be important for weakly-allowed or forbidden transitions. Laying emphasis on TPA, the test systems used belong to the category of two-photon active compounds. The initial candidate is dimethylaminonitrodibenzofuran (DMA-NDBF) which has been reported to be a two-photon only caging compound. The other system is a well-known laser dye, a rhodamine derivative of the commercially available rhodamine 101 (Rh101). Rhodamines are also recognized for their excellent TPA characteristics.
The findings for both the test systems show interesting contrasts. The one-photon absorption (OPA) and TPA spectrum together with vibronic couplings present the same lineshape in case of DMA- NDBF and also the HT effects have very weak contributions to the vibronic spectrum. Insignificant HT effects are quite typical for electronically allowed transitions. Overall, the NO2 bending mode exhibits the strongest change in the absorption spectrum upon vibrational pre-excitation, even stronger than in the case of different ring distortion modes that usually show a high VIPER activity. In the case of rhodamine, the vibronic OPA spectrum is pre-dominantly the FC spectrum and the HT couplings have a very weak contribution. The vibronic TPA spectrum is entirely dominated by the HT contributions and hence, the vibrationally resolved TPA spectrum of the rhodamine is a HT-only spectrum. Explanations towards this behaviour have been reported by Milojevich et al. which are holding the change in symmetry of the molecular orbital transitions from the ground to the excited state accountable. No significantly VIPER-active normal modes could be determined owing to the low magnitudes of their dimensionless displacements that are connected to the Huang-Rhys factors. Two ring distortion modes however have been probed but the intensity of their vibrational pre-excitation is observed to be very low.
The other part of this work is concerned with the estimation of the rate of the intramolecular energy transfer within rhodamine-BODIPY dyads. After the investigations on the prospective rhodamine derivatives, the Rho101 derivative shows the highest TPA activity. This linked together with the BODIPY derivative with styryl substituents through an acetylene bond has been probed theoretically as well as experimentally for the excitation energy transfer (EET).
Time-resolved spectroscopic measurements reveal an ultrafast energy transfer process on femtosecond timescales. The theoretical estimation of the EET rates through the Förster theory and the determination of the coupling between the donor and acceptor groups by the transition density cube (TDC) method falls short of the experimental results. Because of this disagreement, quantum dynamics simulations with the multi-layer multi-configuration time-dependent Hartree (ML-MCTDH) method have been performed on an adapted rhodamine-BODIPY molecular dyad which reveal that the energy transfer occurs through transient coherence whose mechanism cannot be described by Förster theory ...
Die vorliegende Dissertationsarbeit behandelt eine umfangreiche Studie des nukleären Rezeptors (NR) TLX (engl. tailless homolog, TLX). Als ligandenaktivierbarer Transkriptionsfaktor ist TLX in Differenzierungs- und Proliferationsprozessen involviert und übernimmt somit eine tragende regulatorische Rolle in der Neurogenese von neuronalen Stammzellen87,88. Zahlreiche Studien haben gezeigt, dass eine fehlgesteuerte TLX-Expression mit gravierenden kognitiven, visuellen und neurodegenerativen sowie tumorigenen Erkrankungen assoziiert ist, sodass TLX ein vielversprechendes Wirkstofftarget mit hohem therapeutischem Potential darstellt94,95,99,100 105. Die pharmakologische Validierung von TLX als neues Wirkstofftarget befindet sich allerdings aufgrund limitierter Verfügbarkeit von validierten und potenten synthetischen und natürlichen kleinen organischen Molekülen in einer frühen Phase. Daher ist das Interesse sehr groß neuartige und wünschenswerterweise selektive TLX-Modulatoren zu generieren109,119-121.
Im Rahmen dieser Dissertationsarbeit wurden zu diesem Zweck mehrere Reportergenassays eingeführt, die die in vitro Aktivitätsstudie von TLX sowohl im Gal4-Hybridformat in Kombination mit Gal4-VP16 als starken Transkriptionsaktivator als auch als TLX-Volllängenprotein in HEK293T-Zellen (engl. human embryonic kidney, HEK293T) erlaubten. Zusätzlich wurde Gal4-TLX in Kombination mit VP16-RXRα untersucht, um bisherige unbekannte potentielle Heterodimer-vermittelte Effekte zu studieren. In einem primären Screeningansatz im Gal4-Format unter Verwendung einer kommerziell erhältlichen Wirkstofffragmentbibliothek und ausgewählter strukturähnlicher Wirkstoffe wurden mehrere Wirkstofffragmentkandidaten identifiziert (30, 34, 39, 45 und 47), die einen attraktiven Ausgangspunkt zur Darstellung von TLX-Modulatoren darstellten. Insgesamt wurden in vier Projekten vier strukturdiverse Chemotypen anhand von Struktur-Wirkungs-Beziehungs-Studien anhand der Aktivität an TLX untersucht. Ausgehend von Fragment 34 beinhaltete das erste Projekt die Identifizierung und Charakterisierung von Xanthinderivaten als inverse TLX-Agonisten. Eine systematische Struktur-Wirkungs-Beziehungs-Studie lieferte mehrere hochpotente Derivate, die auf das Grundgerüst von 8-Phenyltheophyllin (97) basierten. Parallel konnte Istradefyllin (116), welches aktuell zur Behandlung der Parkinson-Erkrankung in den USA und Japan Anwendung findet, als potenter inverser TLX-Agonist identifiziert werden. Mehrere orthogonale zelluläre und zellfreie Experimente klassifizierten die Xanthine als neue erste TLX-Modulatoren. Das zweite Projekt umfasste die Identifizierung und Charakterisierung des unselektiven β-Adrenorezeptorblockers Propranolol (54) ausgehend vom Wirkstofffragment 30. Durch eine vorläufige systematische Struktur-Wirkungs-Beziehungs-Untersuchung der aliphatischen Aminoalkoholseitenkette von 54 konnte die sekundäre Aminogruppe als determinierendes Strukturmotiv für eine Aktivität an TLX bestimmt werden. Weitere Migrations- und Zellviabilitätsexperimente demonstrierten erste phänotypische Effekte in T98G-Glioblastomzellen seitens 54, die TLX-vermittelt sein könnten. Das dritte Projekt behandelte die Darstellung eines potenten neuartigen TLX-Agonisten mit Hilfe eines ligandenbasierten Pharmakophormodells. Das verwendete Pharmakophormodell wurde hierbei unter Verwendung des publizierten Referenzliganden ccrp2 (2) und dem identifizierten Wirkstofffragment 45 aus dem vorherigen Screeningansatz generiert. Durch eine anschließende rationale Fragmentfusion von 45 mit weiteren TLX-Agonisten aus dem Wirkstofffragmentscreening konnte der neuartige potente TLX-Agonist 137h synthetisiert werden, welcher eine verbesserte mikrosomale Stabilität im Vergleich zu 45 und 2 aufwies. Das vierte Projekt beinhaltete die Darstellung neuartiger TLX-Modulatoren mit Hilfe eines Scaffold Hopping Ansatzes. Hierbei wurden essentielle Strukturmotive aus der Xanthin-Struktur-Wirkungs-Beziehung (erstes Projekt) auf weitere Wirkstofffragmente übertragen. Die Validierung dieses Scaffold Hoppings anhand der Verbindung 156 führte anhand eines darauf folgenden kombinatorisch-chemischen Ansatzes zur Darstellung einer Substanzbibliothek (255 Amidrohprodukte). Ein Aktivitätsscreening der Amidrohprodukte deutete in den Reportergenassays auf drei aktive TLX-Modulatoren hin (582, 611 und 629), welche nachträglich gezielt synthetisiert, isoliert und erneut auf Aktivität an TLX validiert wurden. Hierbei hob sich besonders 629 hervor, welches in drei orthogonalen zellulären Reportergenassays TLX-vermittelte Effekte aufwies und zusätzlich einen Bindungseffekt an rekombinanter exprimierter TLX-Ligandenbindedomäne zeigte.
Mit dieser Arbeit konnte mit Hilfe der Einführung diverser TLX-basierter Reportergenassays zur Aktivitätsstudie von TLX mehrere strukturdiverse Liganden als potentielle tool compounds identifiziert und charakterisiert werden. Alle abgeleiteten TLX-Modulatoren können somit als wertvolle neue Startpunkte zur Derivatisierung neuartiger potenter Liganden und somit zu einem Fortschritt in der pharmakologischen Validierung von TLX als Wirkstofftarget dienen.
Despite a high clinical need for the treatment of colorectal carcinoma (CRC) as the second leading cause of cancer-related deaths, targeted therapies are still limited. The multifunctional enzyme Transglutaminase 2 (TGM2), which harbors transamidation and GTPase activity, has been implicated in the development and progression of different types of human cancers. However, the mechanism and role of TGM2 in colorectal cancer are poorly understood. Here, we present TGM2 as a promising drug target.
In primary patient material of CRC patients, we detected an increased expression and enzymatic activity of TGM2 in colon cancer tissue in comparison to matched normal colon mucosa cells. The genetic ablation of TGM2 in CRC cell lines using shRNAs or CRISPR/Cas9 inhibited cell expansion and tumorsphere formation. In vivo, tumor initiation and growth were reduced upon genetic knockdown of TGM2 in xenotransplantations. TGM2 ablation led to the induction of Caspase-3-driven apoptosis in CRC cells. Functional rescue experiments with TGM2 variants revealed that the transamidation activity is critical for the pro-survival function of TGM2. Transcriptomic and protein–protein interaction analyses applying various methods including super-resolution and time-lapse microscopy showed that TGM2 directly binds to the tumor suppressor p53, leading to its inactivation and escape of apoptosis induction.
We demonstrate here that TGM2 is an essential survival factor in CRC, highlighting the therapeutic potential of TGM2 inhibitors in CRC patients with high TGM2 expression. The inactivation of p53 by TGM2 binding indicates a general anti-apoptotic function, which may be relevant in cancers beyond CRC.
Fluorescently labeled nanoparticles are widely used for evaluating their distribution in the biological environment. However, dye leakage can lead to misinterpretations of the nanoparticles’ biodistribution. To better understand the interactions of dyes and nanoparticles and their biological environment, we explored PLGA nanoparticles labeled with four widely used dyes encapsulated (coumarin 6, rhodamine 123, DiI) or bound covalently to the polymer (Cy5.5.). The DiI label was stable in both aqueous and lipophilic environments, whereas the quick release of coumarin 6 was observed in model media containing albumin (42%) or liposomes (62%), which could be explained by the different affinity of these dyes to the polymer and lipophilic structures and which we also confirmed by computational modeling (log PDPPC/PLGA: DiI—2.3, Cou6—0.7). The importance of these factors was demonstrated by in vivo neuroimaging (ICON) of the rat retina using double-labeled Cy5.5/Cou6-nanoparticles: encapsulated Cou6 quickly leaked into the tissue, whereas the stably bound Cy.5.5 label remained associated with the vessels. This observation is a good example of the possible misinterpretation of imaging results because the coumarin 6 distribution creates the impression that nanoparticles effectively crossed the blood–retina barrier, whereas in fact no signal from the core material was found beyond the blood vessels.
The ribosomal S1 protein (rS1) is indispensable for translation initiation in Gram-negative bacteria. rS1 is a multidomain protein that acts as an RNA chaperone and ensures that mRNAs can bind the ribosome in a single-stranded conformation, which could be related to fast recognition. Although many ribosome structures were solved in recent years, a high-resolution structure of a two-domain mRNA-binding competent rS1 construct is not yet available. Here, we present the NMR solution structure of the minimal mRNA-binding fragment of Vibrio Vulnificus rS1 containing the domains D3 and D4. Both domains are homologues and adapt an oligonucleotide-binding fold (OB fold) motif. NMR titration experiments reveal that recognition of miscellaneous mRNAs occurs via a continuous interaction surface to one side of these structurally linked domains. Using a novel paramagnetic relaxation enhancement (PRE) approach and exploring different spin-labeling positions within RNA, we were able to track the location and determine the orientation of the RNA in the rS1–D34 bound form. Our investigations show that paramagnetically labeled RNAs, spiked into unmodified RNA, can be used as a molecular ruler to provide structural information on protein-RNA complexes. The dynamic interaction occurs on a defined binding groove spanning both domains with identical β2-β3-β5 interfaces. Evidently, the 3′-ends of the cis-acting RNAs are positioned in the direction of the N-terminus of the rS1 protein, thus towards the 30S binding site and adopt a conformation required for translation initiation.
Copper perchlorophthalocyanine (CuPcCl16, CuC32N8Cl16, Pigment Green 7) is one of the commercially most important green pigments. The compound is a nanocrystalline fully insoluble powder. Its crystal structure was first addressed by electron diffraction in 1972 [Uyeda et al. (1972). J. Appl. Phys. 43, 5181–5189]. Despite the commercial importance of the compound, the crystal structure remained undetermined until now. Using a special vacuum sublimation technique, micron-sized crystals could be obtained. Three-dimensional electron diffraction (3D ED) data were collected in two ways: (i) in static geometry using a combined stage-tilt/beam-tilt collection scheme and (ii) in continuous rotation mode. Both types of data allowed the crystal structure to be solved by direct methods. The structure was refined kinematically with anisotropic displacement parameters for all atoms. Due to the pronounced crystal mosaicity, a dynamic refinement was not feasible. The unit-cell parameters were verified by Rietveld refinement from powder X-ray diffraction data. The crystal structure was validated by many-body dispersion density functional theory (DFT) calculations. CuPcCl16 crystallizes in the space group C2/m (Z = 2), with the molecules arranged in layers. The structure agrees with that proposed in 1972.
Xenocoumacin (Xcn) 1 and 2 are the major antibiotics produced by the insect-pathogenic bacterium Xenorhabdus nematophila. Although the antimicrobial activity of Xcns has been explored, research regarding their action on mammalian cells is lacking. We aimed to investigate the action of Xcns in the context of inflammation and angiogenesis. We found that Xcns do not impair the viability of primary endothelial cells (ECs). Particularly Xcn2, but not Xcn1, inhibited the pro-inflammatory activation of ECs: Xcn2 diminished the interaction between ECs and leukocytes by downregulating cell adhesion molecule expression and blocked critical steps of the NF-κB activation pathway including the nuclear translocation of NF-κB p65 as well as the activation of inhibitor of κBα (IκBα) and IκB kinase β (IKKβ). Furthermore, the synthesis of pro-inflammatory mediators and enzymes, nitric oxide (NO) production and prostaglandin E2 (PGE2), inducible NO synthase (iNOS), and cyclooxygenase-2 (COX-2), was evaluated in leukocytes. The results showed that Xcns reduced viability, NO release, and iNOS expression in activated macrophages. Beyond these anti-inflammatory properties, Xcn2 effectively hindered pro-angiogenic processes in HUVECs, such as proliferation, undirected and chemotactic migration, sprouting, and network formation. Most importantly, we revealed that Xcn2 inhibits de novo protein synthesis in ECs. Consequently, protein levels of receptors that mediate the inflammatory and angiogenic signaling processes and that have a short half-live are reduced by Xcn2 treatment, thus explaining the observed pharmacological activities. Overall, our research highlights that Xcn2 exhibits significant pharmacological in vitro activity regarding inflammation and angiogenesis, which is worth to be further investigated preclinically.
Acute myeloid leukemia (AML) is one of the most frequently occurring and fatal types of leukemia. Initiated by genetic alterations in hematopoietic stem and progenitor cells, rapidly proliferating cancer cells (leukemic blasts) infiltrate the bone marrow and damage healthy hematopoiesis. Subgroups of AML are defined by underlying molecular and cytogenetic abnormalities, which are decisive for treatment and prognosis. For AML patients that can be intensively treated, the first line treatment remains a combination of cytarabine and anthracycline, which was developed in the 1970s. While this treatment regimen clears the disease and reinstates normal hematopoiesis (complete remission, CR) in 60% to 80% of patients below the age of 60, CR rates in patients above the age of 60 are only 40% to 50%. Relapse and refractory disease are the major cause of death of AML patients, despite large efforts to improve risk-adjusted post-remission therapy with further chemotherapy cycles and, if possible, allogeneic bone marrow transplantation. Elderly patients are particularly difficult to treat because of age-related comorbidities and because their disease tends to relapse more often than the disease of younger patients. Thus, the cure rates of AML vary with age, with 5-year survival rates of about 50% in young patients, and less than 20% in patients above the age of 65 years. With the median age of AML patients being 68 years, the need for novel therapeutic options is immense. The recent approval of eight new agents (venetoclax, midostaurin, gilteritinib, glasdegib, ivosidenib, enasidenib, gemtuzumab ozogamicin and CPX-351 (liposomal cytarabine and daunorubicin)) has added considerably to the therapeutic armamentarium of AML and has increased cure rates in specific subgroups of AML. However, the high heterogeneity among patients, clonal evolution and commonly occurring drug resistance, which cause the high relapse rates, remain a substantial problem in the treatment of AML. Therefore, a better understanding of currently used therapeutics and further development of novel therapeutics is urgently needed.
In recent years, attention has increasingly focused on therapeutic strategies to interfere with the metabolic requirements of cancer cells. The last three decades have provided extensive insights into the diversity and flexibility of AML metabolism. AML cells use different sources of nutrients compared to normal hematopoietic progenitor cells and reprogram their metabolic pathways to fulfill their exquisite anabolic and energetic needs. As a result, they develop high metabolic plasticity that enables them to thrive in the bone marrow microenvironment, where oxygen and nutrient availability are subject to constant change.
Cancer cells, specifically AML cells, have a strong dependency for the amino acid glutamine. Glutamine serves in energy production, redox control, cell signaling as well as an important nitrogen source. The only enzyme capable of de novo glutamine synthesis is glutamine synthetase (GS). GS catalyzes glutamine production from glutamate and ammonium. In AML, the metabolic role and dependency of GS is poorly understood. Here, we investigated the effects of GS deletion on AML growth, and its functional relevance in AML metabolism. Genetic deletion of GS resulted in a significant decrease of cell growth in vitro, and impaired leukemia progression in vivo in a xenotransplantation mouse model. Interestingly, the dependency of AML cell growth on GS was shown to be independent of its functional role in glutamine synthesis. Glutamine starvation did not increase the dependency of the AML cells on GS, nor did increased glutamine availability rescue the GS-knockout-associated growth disadvantage. Instead, functional studies revealed the role of GS in the detoxification of ammonium. GS-deficient cells showed elevated ammonium secretion as well as a higher sensitivity towards the toxic metabolite. Exogenous provision of 15N-labeled ammonium was detoxified by GS-driven incorporation into glutamine. Studies on cells that had gained resistance to GS-knockout-mediated growth inhibition indicated enzymes involved in the urea cycle and the arginine biogenesis pathway to compensate for a loss of GS. Together, these findings unveiled GS as an important ammonium scavenger in AML.
Clinical studies on AML patients revealed increased ammonium concentrations in the blast-infiltrated bone marrow compared to peripheral blood. In line with this finding, proteome and transcriptome analysis of AML blasts showed a significant upregulation of GS in AML compared to healthy progenitors, further indicating its importance in ammonium detoxification.
Analyzing pathways that contribute to ammonium production revealed protein uptake followed by amino acid catabolism as a yet not identified mechanism supporting AML growth. Protein endocytosis and subsequent proteolytic degradation were shown to rescue AML cells from otherwise growth-inhibiting glucose or amino acid depletion. Furthermore, protein metabolization led to the reactivation of the mammalian target of rapamycin (mTOR) signaling pathway, which was deactivated upon leucine and glutamine depletion, revealing protein consumption as an important alternative source of amino acids in AML.
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The DNA damage response (DDR) is a vast network of molecules that preserves genome integrity and allow the faithful transmission of genetic information in human cells. While the usual response to the detection of DNA lesions in cells involves the control of cell-cycle checkpoints, repair proteins or apoptosis, alterations of the repair processes can lead to cellular dysfunction, diseases, or cancer. Besides, cancer patients with DDR alterations often show poor survival and chemoresistance. Despite the progress made in recent years in identifying genes and proteins involved in DDR and their roles in cellular physiology and pathology, the question of the involvement of DDR in metabolism remains unclear. It remains to study the metabolites associated with specific repair pathways or alterations and to investigate whether differences exist depending on cellular origin. The identification of DDR-related metabolic pathways and of the pathways that cause metabolic reprogramming in DDR-deficient cells may produce new targets for the development of new therapies.
In this thesis, nuclear magnetic resonance spectroscopy (NMR) was used to assess the metabolic consequence of the loss of two central DNA repair proteins with importance in diseases context, ATM and RNase H2, in haematological cells. An increase in intracellular taurine was found in RNase H2- and ATM-deficient cells compared to wild-type cells for these genes and in cells after exposition to a source of DNA damage. The rise in taurine does not appear to result from an increase in its biosynthesis from cysteine, but more likely from other cellular processes such as degradation pathways.
Overall, evidence for metabolic reprogramming in haematological cells with faults in DNA repair resulting from ATM or RNase H2 deficiencies or upon exposition to a source of DNA damage is presented in this study.
Famotidine inhibits toll-like receptor 3-mediated inflammatory signaling in SARS-CoV-2 infection
(2021)
Apart from prevention using vaccinations, the management options for COVID-19 remain limited. In retrospective cohort studies, use of famotidine, a specific oral H2 receptor antagonist (antihistamine), has been associated with reduced risk of intubation and death in patients hospitalized with COVID-19. In a case series, nonhospitalized patients with COVID-19 experienced rapid symptom resolution after taking famotidine, but the molecular basis of these observations remains elusive. Here we show using biochemical, cellular, and functional assays that famotidine has no effect on viral replication or viral protease activity. However, famotidine can affect histamine-induced signaling processes in infected Caco2 cells. Specifically, famotidine treatment inhibits histamine-induced expression of Toll-like receptor 3 (TLR3) in SARS-CoV-2 infected cells and can reduce TLR3-dependent signaling processes that culminate in activation of IRF3 and the NF-κB pathway, subsequently controlling antiviral and inflammatory responses. SARS-CoV-2-infected cells treated with famotidine demonstrate reduced expression levels of the inflammatory mediators CCL-2 and IL6, drivers of the cytokine release syndrome that precipitates poor outcome for patients with COVID-19. Given that pharmacokinetic studies indicate that famotidine can reach concentrations in blood that suffice to antagonize histamine H2 receptors expressed in mast cells, neutrophils, and eosinophils, these observations explain how famotidine may contribute to the reduced histamine-induced inflammation and cytokine release, thereby improving the outcome for patients with COVID-19.
Chronic inflammation is characterized by persisting leukocyte infiltration of the affected tissue, which is enabled by activated endothelial cells (ECs). Chronic inflammatory diseases remain a major pharmacotherapeutic challenge, and thus the search for novel drugs and drug targets is an ongoing demand. We have identified the natural product vioprolide A (vioA) to exert anti-inflammatory actions in vivo and in ECs in vitro through inhibition of its cellular target nucleolar protein 14 (NOP14). VioA attenuated the infiltration of microglia and macrophages during laser-induced murine choroidal neovascularization and the leukocyte trafficking through the vascular endothelium in the murine cremaster muscle. Mechanistic studies revealed that vioA downregulates EC adhesion molecules and the tumor necrosis factor receptor (TNFR) 1 by decreasing the de novo protein synthesis in ECs. Most importantly, we found that inhibition of importin-dependent NF-ĸB p65 nuclear translocation is a crucial part of the action of vioA leading to reduced NF-ĸB promotor activity and inflammatory gene expression. Knockdown experiments revealed a causal link between the cellular target NOP14 and the anti-inflammatory action of vioA, classifying the natural product as unique drug lead for anti-inflammatory therapeutics.
Serine-ubiquitination regulates Golgi morphology and the secretory pathway upon Legionella infection
(2021)
SidE family of Legionella effectors catalyze non-canonical phosphoribosyl-linked ubiquitination (PR-ubiquitination) of host proteins during bacterial infection. SdeA localizes predominantly to ER and partially to the Golgi apparatus, and mediates serine ubiquitination of multiple ER and Golgi proteins. Here we show that SdeA causes disruption of Golgi integrity due to its ubiquitin ligase activity. The Golgi linking proteins GRASP55 and GRASP65 are PR-ubiquitinated on multiple serine residues, thus preventing their ability to cluster and form oligomeric structures. In addition, we found that the functional consequence of Golgi disruption is not linked to the recruitment of Golgi membranes to the growing Legionella-containing vacuoles. Instead, it affects the host secretory pathway. Taken together, our study sheds light on the Golgi manipulation strategy by which Legionella hijacks the secretory pathway and promotes bacterial infection.
The vascular endothelium is a monolayer of endothelial cells that builds the inner lining of the blood vessels and constitutes a regulatory organ within the physiological system to sustain homeostasis. Endothelial cells participate in physiological processes including inflammation and angiogenesis. Dysregulation of these processes, however, can evoke or maintain pathological disorders, including cardiovascular and chronic inflammatory diseases or cancer. Although pathological inflammation and angiogenesis represent treatable conditions, current pharmacotherapeutic approaches are frequently not satisfying since their long-term application can evoke therapy resistance and thus reduced clinical efficacy. Consequently, there is an ongoing demand for the discovery of new therapeutic targets and drug leads. Considering that endothelial cells play a critical role in both angiogenesis and inflammation, the vascular endothelium represents a promising target for the treatment of diseases.
Vioprolide A is a secondary metabolite isolated from the myxobacterium Cystobacter violaceus Cb. vi35. Recently, vioprolide A was identified to interact with NOP14, a nucleolar protein involved in ribosome biogenesis. Ribosome biogenesis is an indispensable cellular event that ensures adequate homeostasis. Abnormal alterations in the ribosome biogenesis, referred to as ribosomopathies, however, can lead to an overall increase in the risk of developing cancer. Accordingly, several studies have outlined the involvement of NOP14 in cancer progression and metastasis, and vioprolide A has been demonstrated to exert anti-cancer effects in vitro. However, the impact of vioprolide A and NOP14 on the endothelium has been neglected so far, although endothelial cells are crucially involved in inflammation and angiogenesis under both physiological and pathological conditions.
In the present study, the effect of vioprolide A on inflammatory and angiogenic actions was analysed. In vivo, the laser-induced choroidal neovascularization (CNV) assay outlined a strong inhibitory effect of vioprolide A on both inflammation and angiogenesis. Furthermore, intravital microscopy of the cremaster muscle in mice revealed that vioprolide A strongly impaired the TNF-induced leukocyte-endothelial cell interaction in vivo.
In further experiments, the specific effect of vioprolide A on activation processes of primary human umbilical vein endothelial cells (HUVECs) was examined. According to the in vivo results, vioprolide A decreased the leukocyte-endothelial cell interaction in vitro through downregulating the cell surface expression and total protein expression of ICAM-1, VCAM-1 and E-selectin. Vioprolide A evoked its anti-inflammatory actions via a dual mechanism: On the one hand, the expression of pro-inflammatory proteins, including TNFR1 and cell adhesion molecules, was lowered through a general downregulation of de novo protein synthesis. The inhibition of de novo protein synthesis is most likely linked to the interaction with and inhibition of NOP14 by vioprolide A in HUVECs. On the other hand, the natural product prevented the nuclear translocation and promotor activity of the pro-inflammatory transcription factor NF-ĸB. Interestingly, most anti-inflammatory compounds that interfere with the NF-ĸB signaling pathway prevent NF-ĸB nuclear translocation through recovering or stabilizing the inhibitory IĸB proteins. Vioprolide A, however, decreased rather than stabilized the IĸB proteins and prevented NF-ĸB nuclear translocation through interfering with its importin-dependent nuclear import. By performing siRNA-mediated knockdown experiments, we evaluated the role of NOP14 in inflammatory processes in HUVECs and could establish a causal link between the anti-inflammatory actions of vioprolide A and the deletion of NOP14.
Besides exerting anti-inflammatory actions, we found that vioprolide A potently decreased the angiogenic key features proliferation, migration and sprouting of endothelial cells. Mechanistically, the natural product interfered with pro-angiogenic signaling pathways. Vioprolide A reduced the protein level of growth factor receptors, including VEGFR2, which is the most prominent receptor responsible for angiogenic signaling in endothelial cells. This effect was based on the general inhibition of de novo protein synthesis by the natural product. Downregulation of growth factor receptors impaired the activation of downstream signaling intermediates, including the MAPKs ERK, JNK and p38. To our surprise, however, activation of Akt, another downstream effector of VEGFR2, was increased rather than decreased. Furthermore, vioprolide A lowered the nuclear translocation of the transcriptional coactivator TAZ, which is regulated by the evolutionary conserved Hippo signaling pathway. Interestingly, however, and in contrast to NF-ĸB, TAZ nuclear translocation in mammalian cells seems to be independent of importins. In this context, we found that vioprolide A reduced both the protein level and nuclear localization of MAML1, which is needed to retain TAZ in the nucleus after its successful translocation.
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The SARS-CoV-2 genome encodes for approximately 30 proteins. Within the international project COVID19-NMR, we distribute the spectroscopic analysis of the viral proteins and RNA. Here, we report NMR chemical shift assignments for the protein Nsp3b, a domain of Nsp3. The 217-kDa large Nsp3 protein contains multiple structurally independent, yet functionally related domains including the viral papain-like protease and Nsp3b, a macrodomain (MD). In general, the MDs of SARS-CoV and MERS-CoV were suggested to play a key role in viral replication by modulating the immune response of the host. The MDs are structurally conserved. They most likely remove ADP-ribose, a common posttranslational modification, from protein side chains. This de-ADP ribosylating function has potentially evolved to protect the virus from the anti-viral ADP-ribosylation catalyzed by poly-ADP-ribose polymerases (PARPs), which in turn are triggered by pathogen-associated sensing of the host immune system. This renders the SARS-CoV-2 Nsp3b a highly relevant drug target in the viral replication process. We here report the near-complete NMR backbone resonance assignment (1H, 13C, 15N) of the putative Nsp3b MD in its apo form and in complex with ADP-ribose. Furthermore, we derive the secondary structure of Nsp3b in solution. In addition, 15N-relaxation data suggest an ordered, rigid core of the MD structure. These data will provide a basis for NMR investigations targeted at obtaining small-molecule inhibitors interfering with the catalytic activity of Nsp3b.
Gram-negative bacteria maintain an intrinsic resistance mechanism against entry of noxious compounds by utilizing highly efficient efflux pumps. The E. coli AcrAB-TolC drug efflux pump contains the inner membrane H+/drug antiporter AcrB comprising three functionally interdependent protomers, cycling consecutively through the loose (L), tight (T) and open (O) state during cooperative catalysis. Here, we present 13 X-ray structures of AcrB in intermediate states of the transport cycle. Structure-based mutational analysis combined with drug susceptibility assays indicate that drugs are guided through dedicated transport channels toward the drug binding pockets. A co-structure obtained in the combined presence of erythromycin, linezolid, oxacillin and fusidic acid shows binding of fusidic acid deeply inside the T protomer transmembrane domain. Thiol cross-link substrate protection assays indicate that this transmembrane domain-binding site can also accommodate oxacillin or novobiocin but not erythromycin or linezolid. AcrB-mediated drug transport is suggested to be allosterically modulated in presence of multiple drugs.
Standard cancer therapy research targets tumor cells while not considering the damage on the tumor microenvironment (TME) and its associated implications in impairing therapy response. Employing patients-derived organoids (PDOs) and matched stroma cells or a novel murine preclinical rectal cancer model of local radiotherapy, it was demonstrated that tumor cells-derived IL-1α polarizes cancer-associated fibroblasts towards an inflammatory (iCAFs) phenotype. While numerous studies in different tumor entities highlighted the molecular heterogeneity of CAFs, so far there are no clear findings on their functional heterogeneity and relevance in therapy resistance and response. The present study molecularly characterized iCAFs subpopulation among RCA patients as well as the preclinical mouse model and importantly unraveled the detailed molecular mechanism underlying their contribution to impair therapy response. Mechanistically, iCAFs were demonstrated to be characterized by an upregulation of nitric oxide synthase (iNOS) which triggered accumulation of reactive nitrogen species (RNS) and subsequently an oxidative DNA damage response (DDR). Such a baseline IL-1α-driven DNA damage further sensitized iCAFs to a p53-mediated therapy induced senescence (TIS) causing extensive extracellular matrix (ECM) changes and induction of senescence associated secretory phenotype (SASP) that favored tumor progression and hindered tumor cell death. Moreover, iCAFs reversibility and repolarization into more quiescent like phenotype was demonstrated upon IL-1 signaling inhibition by anakinra, a recombinant IL-1 receptor antagonist (IL1RA). Accordingly, treating mice with anakinra or specific deletion of Il1r1 in CAFs sensitized stroma-rich resistant tumors to chemoradiotherapy (CRT). Similarly, targeting CAFs senescence by senotherapy (venetoclax chemical) or employing Trp53 deficient mice reverted therapy resistance among non-responsive tumors in vivo by reducing ECM deposition and consequently favoring CD8+ T cells intratumoral infiltration posttherapy. Importantly, rectal cancer patients that do not completely respond to neoadjuvant therapy displayed an iCAFs senescence program post-CRT. Moreover, these patients presented a baseline increased CAFs content, a dominant iCAFs signature that correlated with poorer disease-free survival (DFS) and a significantly reduced circulating IL1RA serum levels. While reduced pretherapeutic IL1RN gene expression predicted poor prognosis among RCA patients, IL1RA serum levels were associated with rs4251961 (T/C) single nucleotide polymorphism (SNP) in the IL1RN gene. Finally, functional validation assays revealed that conditioned media of PDOs drove inflammatory polarization of fibroblasts and consequently rendered them sensitive to RNS-mediated DNA damage and TIS. Collectively, the study highlighted a crucial and novel role of a CAFs subset, iCAFs, in therapy resistance among RCA patients, shedding light on their functional relevance by identifying IL-1 signaling as an appealing target for their repolarization and successful targeting. Therefore, it makes sense to combine the newly demonstrated and thoroughly proven therapeutic approach of targeting IL-1 signaling in combination with conventional CRT and possibly immunotherapy. This might have a major impact on RCA therapy and be of immense relevance for other stroma-rich tumors.
Sphingosin 1 Phosphat (S1P) ist ein wichtiger Lipidmediator, der über G Protein gekoppelte Rezeptoren und intrazelluläre Wirkungen vielfältige Wirkungen auslöst und eine Rolle bei der Lymphozytenzirkulation, der Erhaltung der endothelialen Barriere, bei Entzündungsprozessen und Tumorwachstum spielt. Die S1P Lyase (Sgpl1) katalysiert den irreversiblen Abbau von S1P und damit den letzten Schritt des Sphingolipidkatabolismus‘. Ein Fehlen der Sgpl1 bewirkt eine Akkumulation von S1P und anderen Sphingolipiden im Blut und Gewebe, was multiple Organschäden zur Folge hat. Menschen mit S1P Lyase Insuffizienz Syndrom (SPLIS) leiden insbesondere unter steroidresistentem nephrotischem Syndrom, Nebennierenrinden-insuffizienz und neurologischen Störungen. Weitere mögliche Symptome sind Lymphopenie, Hautveränderungen und Dyslipidämien. S1P Lyase defiziente Mäuse weisen sehr ähnliche Organschädigungen auf.
An Sgpl1 Knockoutmäusen war zuerst die massive Akkumulation nicht nur von Sphingolipiden, sondern auch von Cholesterin und Triglyceriden in Blut und Leber aufgefallen. Auch bei SPLIS Patienten wurde eine Hypercholesterinämie beobachtet. Um die Kreuzregulation des Sphingolipid- und Cholesterinmetabolismus besser zu verstehen, sollte die Rolle der Sgpl1 in der Leber, dem Hauptort des Lipidmetabolismus, untersucht werden. Hierzu sollte ein Mausmodell mit einem hepatozytenspezifischen Sgpl1 Knockout (Sgpl1HepKO) etabliert und charakterisiert werden. Dies wurde durch Kreuzen von Sgpl1fl/fl-Mäusen mit Mäusen, welche die Cre-Rekombinase unter dem Albuminpromoter exprimierten, erreicht. Die basale Charakterisierung zeigte, dass diese Mäuse im Gegensatz zu globalen Sgpl1 Knockoutmäusen sowohl im Alter von acht Wochen, als auch im Alter von acht Monaten einen unauffälligen Phänotyp aufwiesen. Das äußere Erscheinungsbild inklusive Leber und Körpergewicht, das Blutbild, die Leberenzyme sowie die Histologie der Leber waren unverändert. Die Analyse der Leberlipide mit Hilfe von Hochleistungsflüssigkeits-chromatographie gekoppelt mit einer Tandem Massenspektrometrie zeigte eine signifikante Akkumulation (≈1,5 2 fach) von S1P, Sphingosin und Ceramiden, aber nicht von Glucosylceramiden und Sphingomyelin in der Leber. Messungen im Plasma zeigten eine Erhöhung mehrerer Ceramide, während der S1P Spiegel normal war. Ferner zeigten Untersuchungen der Galle signifikant erhöhte Konzentrationen an S1P, Dihydro S1P und Glucosylceramiden, jedoch unveränderte Ceramide. Die Ergebnisse legen folgende Schlussfolgerungen nahe: 1. In der Leber kann mit Hilfe von Ceramidsynthasen akkumulierendes Sphingosin in Ceramide umgewandelt werden, welche anschließend ins Blut sezerniert und letztendlich vermutlich von anderen Zellen verstoffwechselt werden. Außerdem ist nicht ausgeschlossen, dass S1P ebenfalls ins Blut sezerniert und dort effektiv abgebaut wird, so dass die S1P Konzentration im Plasma unverändert bleibt. 2. S1P sowie Glucosylceramide werden an die Galle abgegeben und ausgeschieden. 3. Die Sgpl1 in der Leber ist nicht essentiell für die Regulation des Plasma S1Ps, was zuvor vermutet worden war
Eine Analyse der Sterole zeigte in Sgpl1HepKO Mäusen erhöhte Spiegel an Cholesterin und Desmosterol in der Leber. In Übereinstimmung mit der erhöhten Proteinexpression des low density lipoprotein (LDL ) Rezeptors und erniedrigten Konzentrationen des LDL Cholesterins im Plasma, deuten diese Daten auf eine erhöhte Aufnahme von LDL Cholesterin durch die Leber hin. Untersuchungen in der Leber sowie mit primären Hepatozyten zeigten im Gegensatz zu globalen Sgpl1 Knockoutmäusen keine Veränderungen der Peroxisomen-Proliferator-aktiviertem Rezeptor γ Expression. Weitere Gene mit zentraler Rolle wie der Liver X receptor oder die Fettsäuresynthase, waren ebenfalls nicht reguliert. Dieser im Vergleich zu globalen Sgpl1-Knockoutmäusen milde Phänotyp lässt sich durch die deutlich geringere Akkumulation von Sphingolipiden aufgrund der oben beschriebenen Kompensations-mechanismen in Sgpl1HepKO Mäusen erklären.
In weiteren Untersuchungen sollten die Auswirkungen einer Sgpl1-Defizienz an Fibroblasten untersucht werden. Hierzu standen embryonale Fibroblasten aus Sgpl1 Knockoutmäusen zur Verfügung (Sgpl1-/- MEFs). In einer Kooperation mit Dr. Janecke von der Universität Innsbruck standen außerdem humane Fibroblasten eines SPLIS Patienten zur Verfügung.
An Sgpl1-/- MEFs war zuvor eine gestörte Calciumhomöostase festgestellt worden, welche sich durch eine erhöhte zytosolische Calciumkonzentration und vermehrte Calciumspeicherung im Endoplasmatischen Retikulum und in Lysosomen auszeichnete. Die Plasmamembran-Calcium ATPase (PMCA) trägt an Fibroblasten entscheidend zur Regulation der zytosolischen Calciumkonzentration bei. Ihre Expression auf Proteinebene war jedoch in Sgpl1-/- MEFs nicht verändert. Im Rahmen dieser Arbeit wurde durch eine Immunfärbung erstmals festgestellt, dass die PMCA in Sgpl1-/- MEFs nicht vollständig an der Plasmamembran lokalisiert war. Dies könnte der Grund für die erhöhte zytosolische Calciumkonzentration in den Zellen sein. ...