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The SARS virus is the etiological agent of the severe acute respiratory syndrome, a deadly disease that caused more than 700 causalities in 2003. One of its viral proteins, the SARS coronavirus main protease, is considered as a potential drug target and represents an important model system for other coronaviruses. Despite extensive knowledge about this enzyme, it still lacks an effective anti-viral drug. Furthermore, it possesses some unusual features related to its active-site region. This work gives atomistic insights into the SARS coronavirus main protease and tries to reveal mechanistic aspects that control catalysis and inhibition. Thereby, it applies state-of-the-art computational methods to develop models for this enzyme that are capable to reproduce and interpreting the experimental observations. The theoretical investigations are elaborated over four main fields that assess the accuracy of the used methods, and employ them to understand the function of the active-site region, the inhibition mechanism, and the ligand binding. The testing of different quantum chemical methods reveals that their performance depends partly on the employed model. This can be a gas phase description, a continuum solvent model, or a hybrid QM/MM approach. The latter represents the preferred method for the atomistic modeling of biochemical reactions. A benchmarking uncovers some serious problems for semi-empirical methods when applied in proton transfer reactions. To understand substrate cleavage and inhibition of SARS coronavirus main protease, proton transfer reactions between the Cys/His catalytic dyad are calculated. Results show that the switching between neutral and zwitterionic state plays a central role for both mechanisms. It is demonstrated that this electrostatic trigger is remarkably influenced by substrate binding. Whereas the occupation of the active-site by the substrate leads to a fostered zwitterion formation, the inhibitor binding does not mimic this effect for the employed example. The underlying reason is related to the coverage of the active-site by the ligand, which gives new implications for rational improvements of inhibitors. More detailed insights into reversible and irreversible inhibition are derived from in silico screenings for the class of Michael acceptors that follow a conjugated addition reaction. From the comparison of several substitution patterns it becomes obvious that different inhibitor warheads follow different mechanisms. Nevertheless, the initial formation of a zwitterionic catalytic dyad is found as a common precondition for all inhibition reactions. Finally, non-covalent inhibitor binding is investigated for the case of SARS coranavirus main protease in complex with the inhibitor TS174. A novel workflow is developed that includes an interplay between theory and experiment in terms of molecular dynamic simulation, tabu search, and X-ray structure refinement. The results show that inhibitor binding is possible for multiple poses and stereoisomers of TS174.
This work aims at elucidating chemical processes involving homogeneous catalysis and photo–physical relaxation of excited molecules in the solid state. Furthermore, compounds with supposedly small singlet–triplet gaps and therefore biradicaloid character are investigated with respect to their electro–chemical behavior. The work on hydroboration catalysis via a reduced 9,10–diboraanthracene (DBA) was preformed in collaboration with the Wagner group in Frankfurt, more specifically Dr. Sven Prey, who performed all laboratory experiments. The investigation of delayed luminescence properties in arylboronic esters in their solid state was conducted in collaboration with the Marder group in Würzburg. The author of this work took part in the synthesis of the investigated compounds while being supervised by Dr. Zhu Wu. The final project was a collaboration with the group of Anukul Jana from Hyderabad, India who provided the experimental data.
Glucocorticoids (GCs) are small lipophilic compounds that mediate a plethora of biological effects by binding to the intracellular glucocorticoid receptor (GR) which, in turn, translocates to the nucleus and directly or indirectly regulates gene transcription. GCs remain the cornerstone in the treatment for a number of hematological malignancies, including leukemia, lymphoma and myeloma. Extensive literature suggests that the efficacy of GCs stems from their ability to mediate apoptosis. Despite the enormous strides made in our understanding of regulated cell death, the exact mechanism by which GCs cause apoptosis is still unknown. The data obtained so far provide strong evidence that gene transactivation by the GR underlies the initiation phase of GC-induced thymocyte apoptosis. Furthermore, the multicatalytic proteasome, several members of the Bcl-2 family, changes in calcium flux as well as caspases have been identified as important players in the execution phase of GC-mediated cell death. However, the exact sequence of events in this process still remains elusive. A major problem of the current discussion arises from the fact that different cell types, such as thymocytes, peripheral T cells and lymphoma cells are compared without acknowledging their different characteristics and gene expression profiles. Although it is generally assumed that GCs induce apoptosis via a conserved mechanism, this is not supported by any data. In other words, it is possible that thymocytes, peripheral T cells and lymphoma cells may undergo cell death along different pathways. We therefore wondered whether a unique signal transduction pathway is engaged by GCs to initiate and execute cell death in all types of T lymphocytes or whether distinct pathways exist. Therefore, we compared the role of the proteasome, various caspases, the lysosomal compartment and other factors in GC-induced apoptosis of murine thymocytes and peripheral T cells as well as T-ALL lymphoma cells. Our findings show that the initiation phase of GC-induced apoptosis is similar irrespective of the differentiation state of the cell. Apoptosis in both thymocytes and peripheral T cells is mediated by the GR and depends on gene transcription. In contrast, the execution phase significantly differs between thymocyte and peripheral T cells in its requirement for a number of signal transduction components. Whilst in thymocytes, the proteasome, caspases 3, 8 and 9 as well as cathepsin B play an important role in GC-induced apoptosis, these factors are dispensable for the induction of cell death in peripheral T cells. In contrast, changes in the expression and intracellular location of Bcl-2 family members do not appear to contribute to GC-induced apoptosis in either cell type. Importantly, our observation that GC treatment of thymocytes leads to an activation of the lysosomal protease cathepsin B and that this is an essential step in the induction of cell death by GCs, is the first indication that a lysosomal amplification loop is involved in this process. Analysis of GC-induced apoptosis in several T-ALL cell lines further indicates that the signaling pathway induced by GCs in thymocytes but not in peripheral T cells is shared by all lymphoma cell-types analyzed. Given the therapeutic importance of high-dose GC-therapy for the treatment of hematological malignancies, this finding could potentially form a basis for new anti-cancer strategies in the future, which specifically target tumor cells whilst leaving peripheral T cells of patients untouched.