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Infections with multidrug resistant bacterial strains like Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa or Acinetobacter baumanii that can accumulate resistance mechanisms against different groups of drugs cause increasing problems for the health care system. Multidrug efflux pumps are able to transport different classes of substances, providing a basic resistance to different antibiotics. Especially when they are overexpressed they can keep bacterial cells alive under antibiotic pressure unless other high level resistance mechanisms like expression of β-lactamases are established. One example for a clinically relevant multidrug efflux pump is the AcrAB/TolC tripartite system of E. coli, that transports a variety of different substrates, including besides antibiotics dyes, detergents, bile salts and organic compounds from the periplasm or the inner membrane out of the cell. AcrB is the inner membrane component of the protein complex that determines not only the substrate specificity of the tripartite system but energises the transport through the whole system process via proton transduction as well. TolC is the outer membrane spanning protein that forms a pore in the outer membrane enabling the system to transport drugs over the latter out of the cell. The periplasmic membrane fusion protein AcrA connects AcrB and TolC in the periplasm completing the channel from the periplasm, respective the inner membrane to the extracellular space. AcrB assembles as trimers, in asymmetric crystal structures each of the protomers adapts a different conformation designated L(oose), T(ight) and O(pen). In the protomers tunnels open up and collaps in different conformations. In the L protomer a periplasmic cleft opens up that can initially bind substrates to the periplasmic part of AcrB. In the T conformation the deep binding pocket opens that is assumed to bind substrates tightly that were bound to the access pocket before. As well in the T conformation a second pathway leading to the deep binding pocket opens that can guide substrates from a groove between transmembrane helices TM7, TM8 and TM9, the TM8 groove, that is connected with socalled tunnel 1 that ends in the deep binding pocket. In the O conformation a new tunnel opens that connects the collapsing deep binding pocket with the periplasmic space, respective the channel through the periplasmic space formed from AcrA and TolC. Substrates were cocrystallised in access and deep binding pocket verifying their role in substrate transport. In the TM8 groove in high resolution crystal structures DDM molecules were cocrystallised in L and T conformation, indicating that the AcrB substrate DDM may utilise this entrance to the deep binding pocket. The asymmetry observed in the AcrB trimers trongly suggests a peristaltic pump mechanism. The functional rotation cycle demands communication between the subunits and tight control of substrate load of protomers during the transport to optimise the ration between protons that are transduced and substrates transported. Indeed it was shown that AcrB transport mechanism is positively cooperative for some β-lactam substrates. For the communication between the subunits it was assumed that ionic interaction between ion pairs established between charged amino acids at the interfaces of protomers in different conformations are of special importance. Thus the amino acids engaged in ionic interactions, respective ion pairs D73-K131, E130-K110, D174-K110, R168, R259-E734 were substituted with non-charged amino acids pairwise and phenotypes were determined in plate dilution assays and MIC experiments. No evidence for a general, substrate independent, reduction of AcrB activity, that would be expected when the ionic residues are of special importance for AcrB function, could be found with the methods applied. Substitutions were not only combined pairwise according to the putative ion pairs but as well in combinations of R168A with D174N, E130Q and K131M. AcrB activity is reduced for the variant R168A_D174N significantly, activity decreases further for quadruple variant E130Q_K131M_ R168A_D174N. Because the reduced activity is only observed in this combination of substitutions the phenotype must result from accumulation of small effects of the single substitutions. R168A may destabilise the protomer interfaces, as its side chain is oriented in direction to the neighbouring protomer at all interfaces, enhancing substratespecific effects of substitutions E130Q, K131M, D174N that are not in all conformations oriented towards the neighbouring protomer but as well along the substrate transport pathway. Further investigations to figure out the details of the effects observed were not conducted because fluctuating expression of the variants hindered experimental procedures.
In another approach TM8 was in focus of the interest. As mentioned above it is a possible substrate entrance in the inner membrane. The linker between TM8 and the periplasmic PC2 subdomain undergoes a coil-to-helix transition when AcrB cycles through L, T and O conformations. Linking the transmembrane part of AcrB that provides the energy for the transport process via proton transduction with the periplasmic part harbouring the major part of the substrate pathway assignes TM8 and the periplasmic linker (859-876) an important role in the function of AcrB. Thus it was investigated with an alanine-scan of residues 859 to 884 and G/P respective P/G exchange followed by phenotype characterisation in growth curve and plate dilution assays of selected variants. In the phenotype determinations none of the variants, except G861P that seems to cause massive sterical restriction in an α-helical region, displayed a general, substrate independent decrease of AcrB activity. Thus it is concluded that the individual properties of amino acids in TM8 and the periplasmic linker are not of general importance for the mechanism of AcrB. The substitution of individual amino acids had impact on uptake of different substrates in plate dilution assays in a substrate dependent manner. The uptake of some substrates, like erythromycin or chloramphenicol is more affected than that of others with rhodamine 6G resistance being only reduced for the G861P variant. A relation between the PSA of substrates and reduced activity of AcrB was observed. in Substrates with higher PSA values are more affected by substitutions in TM8 or periplasmic linker, resulting in the conclusion that substrates with higher PSA are more likely to be taken up via the TM8 groove/tunnel 1 pathway than those with lower PSA values.
Rhabdomyosarcoma is the most common paediatric soft-tissue sarcoma, and for tumour recurrence, the prognosis is still unfavourable. The current standard therapy consisting of surgery, radiation and combined chemotherapy does not consider the specific biology of this tumour.
Histone deacetylases (HDACs) and the Lysine-specific demethylase-1 (LSD1) are two epigenetic modifiers which are both part of repressor complexes leading to transcriptional silencing of target genes. Whereas HDACs lead to deacetylation of several lysine-residues within the histone tail, LSD1 is specific for demethylation of H3K4me2 and H3K4me1, as well as in a different context for H3K9me2. Rhabdomyosarcoma is reported to harbour high levels of LSD1, but the functional relevance is yet unclear. HDAC inhibition proved to be effective as single agent treatment, however, the proximity of HDAC1/2 and LSD1 in repressor complexes at the DNA implies a suitable rationale for a combination therapy potentially leading to cooperative effects on target gene transcription. In this study, we aimed to evaluate the potential of a combined LSD1 and HDAC inhibition for cell death induction in rhabdomyosarcoma cell lines. Whereas LSD1 inhibitors failed to induce cell death on their own, the combined inhibition of HDACs and LSD1 resulted in highly synergistic cell death induction. This effect extended to several combinations of LSD1 and HDAC inhibitors as well as to four different rhabdomyosarcoma cell lines, two of embryonal and two of alveolar histology.
With the use of the HDAC inhibitor JNJ-26481585 and the reversible LSD1 inhibitor GSK690, we demonstrated that the cell death induced by the combination matches with the details of intrinsic mitochondrial apoptosis. JNJ-26481585/GSK690-induced cell death is partially caspase-dependent and leads to caspase cleavage, followed by substrate cleavage as shown for PARP, as well as loss of the mitochondrial membrane potential.
Furthermore, JNJ-26481585 and GSK690 acted together to transcriptionally upregulate the proapoptotic proteins NOXA, BIM and BMF, which resulted in respective changes on protein level for both cell lines. However, the antiapoptotic BCL-2 family proteins BCL-2, MCL-1 and BCL-xL displayed only minor changes in protein levels upon treatment with GSK690 and JNJ-26481585, which did not rely on transcriptional activity. Therefore, the increase in proapoptotic proteins induces a shift towards proapoptotic signalling at the mitochondrial membrane. This shift is functionally relevant since knockdown of a proapoptotic protein or overexpression of one of the antiapoptotic proteins BCL-2 and MCL-1, as well as a stabilized mutant MCL-1, can significantly protect from GSK690/JNJ-26481585-induced cell death.
Knockdown of the mitochondrial membrane protein BAK, which is directly guarding the mitochondrial membrane integrity, potently protected from GSK690/JNJ-26481585- induced cell death, directly linking the shift in the BCL-2 family proteins to the observed loss of mitochondrial membrane potential and the further downstream activation of caspases. Furthermore, treatment with JNJ-26481585 and GSK690 resulted in a cell cycle arrest in G2/M phase, indicating additional effects on the tumour cells beside apoptosis induction. Taken together, the combined inhibition of LSD1 and HDACs is a promising strategy for rhabdomyosarcoma treatment.
Pulsed electron-electron double resonance (PELDOR), also called Double Electron-Electron Resonance, (DEER) is a pulsed EPR technique that can provide structural information of biomolecules, such as proteins or nucleic acids, complementary to other structure determination methods by measuring long distances (from 1.5 up to 10 nm) between two paramagnetic labels. Incorporation of the rigid Ç-label pairwise into DNA or RNA molecules enables the determination not only of the distance but also of the mutual orientation between the two Ç-labels by multi-frequency orientation-selective PELDOR data (X-, Q- and G-band frequencies). Thus, information about the orientation of secondary structure elements of nucleic acids can be revealed and used as additional angular information for structure determination. Since Ç does not have motion independent from the helix where it resides, the conformational flexibility of the nucleic acid molecule can be directly determined. This thesis demonstrates the advancement of PELDOR spectroscopy, beyond its original scope of distance measurements, to determine the mutual orientation between two rigid spin labels towards the characterization of the conformational space sampled by highly flexible nucleic acid molecules. Applications of the methodology are shown on two systems: a three-way junction, namely a cocaine aptamer in its bound-state, and a two-way junction, namely a bent DNA.
More in detail, the conformational changes of the cocaine aptamer upon cocaine binding were investigated by analysis of the distance distributions. The cocaine-bound and the unbound states could be differentiated by their conformational flexibility, which decreases in the presence of the ligand. Moreover, the obtained distance distributions revealed a small change in the mean distance between the two spin labels upon cocaine binding. This indicates a ligand-induced conformational change, which presumably originates at the junction where cocaine is known to bind. The investigation of the relative orientation between the two spin-labeled helices of the aptamer revealed further structural insights into the conformational dynamics of the cocaine-bound state. The angular information from the orientation-selective PELDOR data and the a priori knowledge about the secondary structure of the aptamer were helpful in obtaining a molecular model describing its global folding and flexibility. In spite of a large flexible aptamer, the kink angle between the Ç-labeled helices was found to be rather well-defined.
As for the bent DNA molecule, a two-step protocol was proposed to investigate the conformational flexibility. In the first step, a database with all the possible conformers was created, using available restraints from NMR and distance restraints derived from PELDOR. In a second step, a weighted ensemble of these conformers fitting the multi-frequency PELDOR data was built. The uniqueness of the obtained structural ensemble was checked by validation against an independent PELDOR data set recorded at a higher magnetic field strength. In addition, the kink and twist angle pairs were determined and the resulting structural ensemble was compared with the conformational space deduced both from FRET experiments and from the structure determined by the NMR restraints alone.
Overall, this thesis underlines the potential of using PELDOR spectroscopy combined with rigid spin labels in the context of structure determination of nucleic acids in order to determine the relative orientation between two helices, the conformational flexibility and the conformational changes of nucleic acid molecules upon ligand binding.
Cancer cells, in general and especially Rhabdomyosarcoma (RMS) cells have been reported to be highly susceptible to oxidative stress. Based on this knowledge we examined whether the inhibition of the two main antioxidant defense pathways, i.e. the thioredoxin (TRX) and the glutathione (GSH) system, represents a possible new strategy to induce cell death in RMS. To do so, we combined the -glutamylcysteine synthetase (γGCL) inhibitor buthionine sulfoximine (BSO) or the cystine/glutamate antiporter (xc-) inhibitor erastin (ERA), both GSH depleting enzymes, with the thioredoxinreductase (TrxR) inhibitor auranofin (AUR) to evaluate synergistic cell death in the alveolar RMS (ARMS) cell line RH30 and the embryonal RMS (ERMS) cells RD.
Furthermore, we tried to unravel the underlying molecular mechanisms of AUR/BSO or AUR/ERA treatment in RMS cells. Thereby we showed that AUR/BSO as well as AUR/ERA treatment leads to proteasome inhibition characterized by the accumulation of ubiquitinated proteins, which is in agreement with the already published ability of AUR to inhibit proteasomeassociated deubiquitinases (DUBs) aside from TrxR. As a consequence, the protein levels of ubiquitinated short-lived proteins, like NOXA and MCL-1, increase upon treatment with AUR/BSO or AUR/ERA. Consistently, we could detect an increased binding of NOXA to MCL-1. Interestingly, not only NOXA protein levels but also mRNA levels rise upon treatment, pointing to a transcriptional regulation of pro-apoptotic NOXA through AUR/BSO or AUR/ERA combination treatment. The fact that siRNA mediated knockdown of NOXA rescues cells from combination treatment-induced cell death strengthens the role of NOXA as an important regulator of cell death induction. Apart from proteasome inhibition and subsequent NOXA accumulation, AUR cooperates with BSO or ERA to trigger BAX/BAK activation, which is needed for cell death induction, too. Additionally, loss of mitochondrial membrane potential (MMP) as well as caspase activation and PARP cleavage is detected after treatment of RMS cells with AUR/BSO or AUR/ERA.
Except of apoptotic cell death we also detected features of iron-dependent ferroptosis after treatment with AUR/BSO or AUR/ERA. This is not surprising, since BSO and ERA already have been described to induce ferroptotic cell death. Although lipid peroxidation takes place in both cell lines, only in RH30 cells, cell death seems to be partially ferroptosis-dependent, since especially in this cell line AUR/BSO- or AUR/ERA-induced cell death can be rescued with different ferroptosis inhibitors.
Although both combination treatments, AUR/BSO as well as AUR/ERA, induce production of reactive oxygen species (ROS), only the thiol-containing ROS scavengers GSH and its precursor N-acetylcysteine (NAC), but not the non-thiolcontaining antioxidant α-Tocopherol (α-Toc), consistently prevent proteasome inhibition, NOXA accumulation and cell death.
Additionally, we demonstrated that BSO and ERA abolish AUR-mediated upregulation of GSH thereby releasing the AUR cytotoxic effect on RMS cells, in line with the described ability of cysteines to inhibit the function of AUR. Together, this points to the conclusion that GSH depletion, rather than an increase in ROS levels, is important for AUR/BSO- or AUR/ERA-induced cell death.
In conclusion, through revealing that the antitumor activity of AUR is enhanced in combination with GSH depleting agents, we identified redox homeostasis as a new and promising target for the treatment of RMS cells.
Bacteria are highly organized organisms which are able to adapt to and propagate under a multitude of environmental conditions. Propagation hereby requires reliable chromosome replication and segregation which has to occur cooperatively with other cellular processes such as transcription, translation or signaling. Several mechanisms were proposed for segregation of the Escherichia coli (E. coli) chromosome, for example a mitotic-like active segregation model or entropy-based passive chromosome segregation. Another segregation model suggests coupled transcription, translation and insertion of membrane proteins (termed "transertion"), which links the replicating chromosome (nucleoid) to the growing cell cylinder.
Fluorescence microscopy was widely used to provide evidence for a distinct segregation model. However, the dynamic nature of bacterial chromosomes, the small bacterial size and the optical resolution limit of ~ 200-300 nm impair unveiling the underlying mechanisms. With the emergence of super-resolution fluorescence microscopy techniques and advanced labeling methods, a new toolbox became available enabling scientists to visualize biomolecules and cellular processes in unprecedented detail. Single-molecule localization microscopy (SMLM) represents a set of super-resolution microscopy techniques which relies on the temporal separation of the fluorescence signal and detection of single fluorophores. Separation can be achieved using photoactivatable or -convertible fluorescent proteins (FPs) in photoactivated localization microscopy (PALM), photoswitchable organic dyes in direct stochastic optical reconstruction microscopy (dSTORM) or dynamically binding fluorescent probes in point accumulation for imaging in nanoscale topography (PAINT). In all these techniques, the fluorescence emission pattern of single fluorophores is spatially localized with nanometer-precision. An artificial image is finally reconstructed from the coordinates of all single fluorophores detected. This provides a spatial resolution of ~ 20 nm, which is perfectly suited to investigate cellular processes in bacteria. In this thesis, different SMLM techniques were applied to study fundamental processes in E. coli. This includes determination of protein copy numbers and distributions as well as the nanoscale organization of nucleic acids and lipids.
A novel labeling approach was applied and used for super-resolution imaging of the E. coli nucleoid. It is based on the incorporation of the modified thymidine analogue 5-ethynyl-2’- deoxyuridine (EdU) into the replicating chromosome. Azide-functionalized organic fluorophores can be covalently attached to the ethynyl group of incorporated EdU bases using a copper-catalyzed "click chemistry" reaction. Under the investigated growth condition, E. coli cells exhibited overlapping replication cycles, which is commonly referred to as multi-fork replication and enables cells to divide faster than they can replicate the entire chromosome. dSTORM imaging of such labeled nucleoids revealed chromosome features with diameters of 50 - 200 nm, representing highly condensed DNA filaments. Sorting single E. coli cells by length allowed visualizing structural changes of the nucleoid throughout the cell cycle. Replicating nucleoids segregated and expanded along the bacterial long axis, while constantly covering the entire width of the cell. Measuring cell and nucleoid length revealed a relative nucleoid expansion rate of 78 ± 6 %. At the same time, nucleoids populated 63 ± 8 % of the cell length, almost exclusively being localized to the cylindrical part of the cell. This value was hence normalized to the cylindrical fraction of the cell, yielding a value of 79 ± 10 % (nucleoid-populated fraction of the cell cylinder), which is in good agreement with the observed relative nucleoid expansion rate. These results therefore support a growth-mediated segregation model, in which the chromosome is anchored to the inner membrane and passively segregated into the prospective daughter cells upon cell growth. 3-dimensional dSTORM imaging of labeled nucleoids confirmed that compacted nucleoids helically wrap along the inner membrane. Similar results were obtained by imaging orthogonally aligned E. coli cells using a holographic optical tweezer approach.
In order to visualize particular proteins together with the nucleoid, several correlative imaging workflows were established, facilitating multi-color SMLM imaging in single E. coli cells. These workflows bypass prior limitations of SMLM, including destruction of FPs by reactive oxygen species in copper-catalyzed click reactions or incompatibility of PALM imaging with dSTORM imaging buffers. A sequential SMLM imaging routine was developed which is based on postlabeling and retrieval of previously imaged cells. Optimal imaging conditions can be maintained for each fluorophore, enabling to extract quantitative information from PALM measurements while correlating the protein distribution to the nucleoid ultrastructure within the highly resolved cell envelope. Applying this workflow to an E. coli strain carrying a chromosomal rpoC - photoactivatable mCherry (PAmCh) fusion, transcribing RNA polymerase (RNAP) was found to be localized on the surface of nucleoids, where active genes are exposed towards the cytosol. During growth in nutrient-rich medium, the majority of RNAP molecules was bound to the chromosome, thus ensuring that the RNAP pool is equally distributed to the daughter cells upon cell division. This work represented the first triple-color SMLM study performed in E. coli cells. ...
A great challenge in life sciences remains the site-specific modification of proteins with minimal perturbation for in vitro as well as in vivo studies. Therefore, different chemoselective reactions and semi-synthetic techniques such as native chemical ligation or intein-mediated protein splicing have been established. They enable a site-specific incorporation of chemical reporters into proteins, such as organic fluorophores or unnatural amino acids. In this PhD Thesis, protein trans-splicing was guided by minimal high-affinity interaction pairs to trace proteins in mammalian cells. In addition, the temporal modulation of cellular processes by photo-cleavable viral immune evasins was achieved.
Protein trans-splicing mediated by split inteins is a powerful technique for site-specific and 'traceless' protein modifications. Despite recent developments there is still an urgent need for ultra-small high-affinity intein tags for in vitro and in vivo approaches. So far, only a very few in-cell applications of protein trans-splicing are reported, all limited to C-terminal protein modifications. Here, a strategy for covalent N-terminal intein-mediated protein labeling at sub-nanomolar probe concentrations was developed. Combined with the minimalistic Ni-trisNTA/His-tag interaction pair, the affinity between the intein fragments was increased 50-fold (KD ~ 10 nM). Site-specific and efficient 'traceless' protein modification by high-affinity trans-splicing is demonstrated at nanomolar concentrations in mammalian cells.
High background originating from non-reacted, 'always-on' fluorescent probes still is a crucial issue in life sciences. Covalent labeling approaches with simultaneous activation of fluorescence are advantageous to increase sensitivity and to reduce background signal. Therefore, high-affinity protein trans-splicing was combined with fluorophore/quencher pairs for online detection of covalent N-terminal protein labeling in cellular environments. Substantial fluorescence enhancement at nanomolar probe concentrations was achieved. This ultra-small fluorogenic high-affinity split intein system is an unprecedented example for real-time monitoring of the trans-splicing reaction in cell-like environments as well as for protein labeling with fluorogenic probes at nanomolar concentrations.
To extend the field of chemical immunology and to address spatiotemporal aspects in adaptive immune response, new tools to control antigen processing are required. Therefore, synthetic photo-conditional viral immune evasins were designed to modulate antigen processing on demand. By using light, the time and dose controlled antigen translocation by the transporter associated with antigen processing (TAP) was triggered with response in the second regime. Peptide delivery and loading by the peptide-loading complex (PLC) was rendered inactive, whereas blocking was abolished in a light-controlled fashion to inactivate the synthetic viral immune evasin ICP47 along with simultaneous activation of the antigen presentation pathway. Lightresponsive peptide translocation by the TAP complex was assayed in vitro by utilizing microsomes isolated from professional antigen presenting B-cell lymphomas (Raji). To extend these studies, suppression and photo-controlled rescue of antigen presentation was examined at single-cell resolution in human primary immune cells.
Native chemical ligation interconnects peptide chemistry with recombinantly expressed proteins. This technique was applied to generate the semi-synthetic full-length ICP47. Although this approach was realized, the low product yield was not sufficient for further functional studies. Therefore, full-length ICP47 was consecutively generated by utilizing a full synthetic four-fragment ligation approach. However, this synthetic viral immune evasin was not able to block peptide translocation in a robust way.
This thesis is concerned with quantum dynamical propagation methods suitable for high-dimensional systems, and their application to excitation energy transfer (EET), electron transfer (ET), and intra-molecular vibrational redistribution (IVR) in molecular aggregates. The theoretical description of these processes, which are often ultrafast – with time scales in the range of femtoseconds to picoseconds – is challenging, both with regard to quantum dynamical simulations and electronic structure calculations.
The present thesis comprises two parts. The first part concerns the implementation of a novel quantum dynamical method based on Gaussian Wavepackets (GWPs): the 2-Layer Gaussian-MCTDH (2L-GMCTDH) method. This method, which has recently been proposed in [S. Römer, M. Ruckenbauer, I. Burghardt, The Journal of Chemical Physics, 2013, 138, 064106] was implemented in a Fortran90 code and applied to various high-dimensional test systems. The second part of the thesis addresses the combined electronic structure and dynamical study of a novel type of donor-acceptor systems that have been investigated in a joint project with experimental collaboration partners at Strasbourg University. In both parts, numerical applications focus on high-dimensional model Hamiltonians for EET and ET processes.
Regarding the first part, the interest of using GWP-based methods is two-fold: First, GWPs represent spatially localized basis sets that are useful for on-the-fly dynamics in conjunction with electronic structure calculations. Second, they are naturally suited for the explicit representation of quantum mechanical system-bath type problems where a large number of vibrational bath modes are weakly perturbed from equilibrium. In this context, various methods exist that are based upon classically evolving GWP bases. A major improvement results from variational methods which involve optimized, non-classical GWP trajectories. In particular, the variational Gaussian-based Multi-Configuration Time-Dependent Hartree (GMCTDH) and its variational Multi-Configurational Gaussians (vMCG) variant were originally derived as semiclassical variants of the Multi-Configuration Time-Dependent Hartree (MCTDH) method. However, the G-MCTDH and vMCG methods mostly use Frozen Gaussian (FG) basis sets that are far less flexible than the single-particle (SPF) representation of standard MCTDH. As a consequence, a significantly larger number of GWPs are generally required to reach convergence. To remedy the lack of flexibility of the FG basis sets, the abovementioned two-layer (2L-G-MCTDH) approach has been introduced: Here, the first layer is composed of flexible SPFs, while the second layer is composed of low-dimensional FGs. The numerical scaling properties are significantly improved as compared with the conventional G-MCTDH and vMCG schemes. The first implementation of the method in an in-house Fortran90 code is presented, along with applications to (i) a model of site-to-site vibrational energy flow in the presence of intra-site vibrational energy redistribution (IVR) and (ii) a multidimensional donor-acceptor electron transfer system described within a linear vibronic coupling model. The second system relates to a model for ET at an oligothiophene-fullerene interface relevant to organic photovoltaics. Besides the description of the implementation, a detailed assessment of the convergence properties and comparison with multi-layer MCTDH (ML-MCTDH) benchmark calculations is presented. Finally, a perspective is given on the future combination with the existing ML-MCTDH scheme; indeed, such a combination is straightforward since the first layer of the 2L-G-MCTDH approach can be chosen to be orthogonal.
Regarding the second part of the thesis, two generations of a novel donor-acceptor (DA) system for organic photovoltaics applications, involving self-assembled block co-oligomers DA dyads and triads with perylene-diimide (PDI) accepter units, are addressed within a collaborative project with S. Haacke and S. Mery (University of Strasbourg). Based upon detailed excited-state electronic structure investigations along with quantum dynamical and kinetic studies, the relevant ET formation and recombination steps are characterized quantitatively, in view of optimizing the chemical design and reducing recombination losses.
In a first-generation variant of the abovementioned DA systems, which involves liquid-crystalline triads, we were able to show that a highly efficient inter-chain ET process prevails over intra-molecular ET, leading to fast recombination. Due to the latter, this system turns out to be inefficient for photovoltaic applications. To fully understand the elementary steps, high-dimensional quantum dynamics simulations were carried out using the ML-MCTDH method, in collaboration with Matthias Polkehn from our group. In the second-generation variant, which is in the focus of the present thesis, both the nanomorphology and the chemical design were modified. The present work, focuses upon the aspect of chemical design, by characterizing a series of modified DA’s, with donor units of varying length while the PDI accepter units remain unchanged. The intra-molecular ET is observed in these systems, but the processes are comparatively slow, of the order of tens to hundreds of picoseconds. Hence, a kinetic analysis using the Marcus-Levich-Jortner rate theory is employed. Among the main results of the study is that addition of an electron donating amine unit strongly increases the lifetime of the charge-separated state, and therefore reduced recombination losses.
Overall, the present thesis shows how a combination of high-dimensional quantum dynamics, electronic structure calculations, and vibronic coupling model Hamiltonians can be employed to obtain an accurate picture of EET, ET, and IVR in high-dimensional molecular assemblies. Furthermore, the 2L-GMCTDH method paves the way for accurate and efficient on-the-fly calculations; a suitable set-up for such calculations is currently in progress.
In dieser Dissertation wurde die Rolle des Proteins Carboxypeptidase E (CPE) im Glioblastom (GBM) untersucht. Ursprünglich wurde CPE in der neuroendokrinen Regulation beschrieben, wo es die Reifung der meisten Neuropeptide und Hormone reguliert und somit Einfluss auf Stoffwechsel und humorale Effekte hat (Fricker et al., 1982; Fricker & Snyder, 1982 and 1983; Davidson & Hutton, 1987; Shen & Loh, 1997; Lou et al., 2005). Ab 1989 wurde CPE in unterschiedlichen Tumorentitäten nachgewiesen (Grimwood et al., 1989; Manser et al., 1991), jedoch ohne Hinweise, welche Bedeutung das Protein dort haben könnte. Erst im letzten Jahrzehnt konnten sowohl pro- als auch anti-tumorigene Wirkungen von CPE gezeigt werden. Die beschriebenen Wirkungen von CPE sind jedoch von dessen Isoform abhängig. Das ∂(delta)N-trunkierte CPE zeigte sich mit erhöhtem Tumorwachstum und schlechter Überlebensprognose in verschiedenen Krebsentitäten assoziiert (Murthy et al., 2010; Lee et al., 2011; Zhou et al., 2013). Im Gegensatz dazu verringerte sezerniertes CPE (sCPE) im Fibrosarkom und Glioblastom die Zellmigration, was einen anti-tumorigenen Effekt suggeriert (Höring et al., 2012; Murthy et al., 2013a). Die Molekularmechanismen, die für die Regulation der Migration zuständig sind, sind jedoch kaum untersucht. Die meisten Untersuchungen von sCPE in Normal- und Tumorgewebe beschränken sich hauptsächlich auf Apoptose und Zellüberleben (Skalka et al., 2013; Murthy et al., 2013b; Cheng et al., 2013; Selvaraj et al., 2015; Cheng et al., 2015). Die vorliegende Arbeit ist demzufolge die erste Studie, die sich dem Mechanismus der Migrationsregulation durch sCPE im Glioblastom widmet.
Humane Gliome stellen die größte und bösartigste Gruppe hirneigener Tumore dar. Bösartige Gliome sind höchst resistent gegen alle zurzeit verfügbaren Behandlungsmethoden. Einer der Hauptgründe dafür ist, dass die Tumorzellen durch diffuse Infiltration in das Gehirn einwandern können. Ferner sind Gliomzellen metabolisch sehr aktiv und können sich dadurch an schnell verändertes Milieu anpassen (Fack et al., 2015; Demeure et al., 2016). Über die grundlegenden Mechanismen für diese Art des infiltrierenden Tumorwachstums ist bisher noch nicht viel bekannt. Zurzeit sind nur wenige Schlüsselfaktoren beschrieben, die den sogenannten Mechanismus der Migration oder Proliferation ("go or grow") in bösartigen Tumoren beeinflussen: wenige Transkriptionsfaktoren, miRNAs sowie metabolische Faktoren. Interessanterweise, sind miRNAs zum Teil mit der Regulation des Metabolismus in Tumorzellen assoziiert. Eine vorangehende Studie aus unserem Labor hat sCPE aufgrund seines Potentials, Zellwanderung zu verringern, als einen weiteren Schlüsselfaktor identifiziert. Wir konnten zeigen, dass sCPE in der Gliomzelllinie LNT-229 zur einer differentiellen Regulation von Migration und Proliferation führt (Höring et al., 2012). Die vorliegende Arbeit widmet sich nun der Frage nach den genauen zugrundeliegenden Mechanismen, wie sCPE seine Effekte auf molekularer Ebene vermittelt. Darüber hinaus soll geklärt werden, ob sCPE auch in der metabolischen Adaptation eine Rolle spielt und dadurch ebenfalls die Gliomzellmigration beeinflußen kann.
Proteinen die ExHepatitis C ist eine entzündliche Erkrankung der Leber, die durch das Hepatitis-C-Virus (HCV) verursacht wird. Trotz vieler Bemühungen ist heutzutage immer noch keine prophylaktische Vakzinierung verfügbar. Neuartige Therapien versprechen eine hohe Heilungsrate, sind aber mit hohen Kosten verbunden. HCV induziert oxidativen Stress, welcher für das Auftreten und die Progression der Pathogenese eine zentrale Rolle spielt. Um zellulären Stress (z.B. durch ROS) entgegenzuwirken, haben Zellen cytoprotective und detoxifizierende Mechanismen entwickelt, die die zelluläre Homöostase aufrechterhalten. Dabei kontrolliert der redoxsensitive Transkriptionsfaktor Nrf2 als Heterodimer zusammen mit sMaf- pression von cytoprotective und ROS-detoxifizierenden Genen. Vorherige Studien haben gezeigt, dass HCV den Nrf2/ARE-Signalweg beeinträchtigt. Dabei induziert HCV eine Translokation der sMaf-Proteine aus dem Zellkern in das Cytoplasma, wo diese das virale Protein NS3 binden. Im Cytoplasma lokalisierte sMaf-Proteine verhindern dadurch eine Translokation von Nrf2 in den Zellkern. Folglich ist die Expression von Nrf2/ARE-abhängigen cytoprotective Genen inhibiert und intrazelluläre ROS-Spiegel dauerhaft erhöht. Ein weiterer zentraler cytoprotective Mechanismus ist die Autophagie. Sie dient der Aufrechterhaltung der zellulären Homöostase durch den Abbau von defekten Proteinen und Organellen. Des Weiteren ist bekannt, dass Autophagie nicht nur im Laufe von Nährstoffmangel induziert wird, sondern auch durch erhöhte Mengen an ROS. In sämtlichen Studien konnte beobachtet werden, dass Autophagie für die Aufrechterhaltung des viralen Lebenszyklus eine wesentliche Rolle spielt, da sie mit der Ausbildung des membranous web, der Translation, der Replikation und der Freisetzung des Virus interferiert. Ausgehend davon sollte in dieser Arbeit zunächst die Relevanz von HCV-induziertem oxidativen Stress, resultierend aus der Nrf2/ARE-Signalweginhibition, als möglicher Aktivator der Autophagie untersucht werden. Dabei wurde in HCV-positiven Zellen eine Akkumulation von LC3-II beobachtet, was auf eine Induktion der Autophagie schließen lässt. In Übereinstimmung damit wurde eine erhöhte Expression von Autophagie-Markerproteinen in HCV-infizierten PHHs detektiert. Im Laufe der Autophagie wird p62 abgebaut. Somit sollte eine Induktion der Autophagie in einer Verminderung der Menge an p62 resultieren. Nichtsdestotrotz ist eine Akkumulation von p62 in HCV-positiven Zellen nachzuweisen. Dies erscheint zunächst widersprüchlich. Aufgrund der Tatsache, dass die Expression der katalytischen Untereinheit des Proteasoms (PSMB5) Nrf2-abhängig ist, führt die beeinträchtigte Nrf2-Aktivität in HCV-positiven Zellen jedoch zu einer verringerten Aktivität des konstitutiven Proteasoms. Dieser Befund kann auch die erhöhte Halbwertzeit von p62 in HCV-positiven Zellen erklären. Kürzlich wurde ein Zusammenspiel des Nrf2/ARE-Signalwegs und der Autophagie beobachtet. Dabei kann Nrf2 nicht nur über den kanonischen Signalweg aktiviert werden, sondern auch durch eine direkte Interaktion des phosphorylierten Autophagie-Adaptorproteins p62 (pS[349] p62) mit Keap1. In HCV-positiven Zellen können nicht nur eine Zunahme der Gesamtmenge von p62 beobachtet werden, sondern auch erhöhte Mengen an pS[349] p62. Die Berechnung des Quotienten aus pS[349] p62 und p62 zeigt in etwa eine Verdopplung der Menge an pS[349] p62 , was auf eine vermehrte Phosphorylierung von p62 in HCV-positiven Zellen rückschließen lässt. Des Weiteren konnte beobachtet werden, dass erhöhte Mengen an ROS, wie sie auch in HCV-positiven Zellen vorkommen, Autophagie induzieren können, die durch eine Akkumulation von LC3-II und die Zunahme von LC3 Puncta charakterisiert ist. Auch eine Zunahme von pS[349] p62 konnte beobachtet werden. Ferner resultierte die Überexpression der phosphomimetischen Mutante (p62 [S351E]) in einer Akkumulation von LC3-II, was auf die Fähigkeit von pS[349] p62 rückschließen lässt, Autophagie zu induzieren. Eine Modulation der Autophagie mittels der Inhibitoren 3-Methyladenin und Bafilomycin führte zu einer inhibierten Freisetzung von infektiösen viralen Partikeln und unterstreicht damit, dass der Autophagie eine essentielle Bedeutung bei der Freisetzung viraler Partikel zukommt. Eine HCV-Infektion wird sowohl von erhöhten Mengen an ROS als auch von einer Induktion der Autophagie begleitet. Dementsprechend führte eine Verminderung des intrazellulären Radikalspiegels durch eine Inkubation mit den Radikalfängern PDTC und NAC zu geringeren Mengen an LC3-II und pS[349] p62. Dabei konnte auch eine Abnahme der freigesetzten infektiösen viralen Partikel beobachtet werden, was ein Zusammenspiel zwischen erhöhten Mengen an ROS, Induktion der Autophagie und Virusfreisetzung nahelegt. Vorschlag: Erhöhte Mengen an ROS werden durch eine Aktivierung des Nrf2/ARE-Signalwegs detoxifiziert und würden somit den zuvor beschriebenen viralen Mechanismus verhindern. HCV die Aktivierung Nrf2/ARE-regulierter Gene beeinträchtigt, wurde die Hypothese aufgestellt, dass in HCV-positiven Zellen dieser komplexe Mechanismus dazu dient, die Translokation des pS[349] p62-abhängig freigesetzte Nrf2 in den Zellkern zu verhindern. Das wiederum hat eine eingeschränkte Expression von Nrf2/ARE-abhängigen Genen und Detoxifizierung von ROS zur Folge. Um diese Hypothese experimentell zu untersuchen, wurden HCV-positive und negative Zellen cotransfiziert mit dem p62 Wildtyp (p62 [wt]), der p62 phosphomimetischen Mutante (p62 [S351E]) oder einem Kontrollplasmid in Kombination mit einem Reporterkonstrukt, welches die Nrf2-Aktivierung darstellt (OKD48). Während in HCV-negativen Zellen im Vergleich zum p62 [wt] eine Transfektion mit p62 [S351E] zu einer signifikanten Aktivierung des Nrf2-abhängigen Reportergens führt konnte dies in HCV-positiven Zellen nicht beobachtet werden. Zusammengenommen beschreiben diese Ergebnisse einen neuartigen Mechanismus wie HCV das Zusammenspiel zwischen dem Nrf2/ARE-Signalweg, erhöhten Mengen an ROS und Autophagie beeinflusst. Dabei übt HCV einen negativen Effekt auf den Nrf2/ARE-Signalweg aus, um dem pS[349] p62-abhängig freigesetzten Nrf2 zu entkommen. Folglich werden erhöhte Mengen an ROS aufrechterhalten, die eine Induktion der Autophagie ermöglichen, welche für die Freisetzung viraler Partikel essentiell ist.
Riboswitches are an important class of regulatory RNA elements that respond to cellular metabolite concentrations to regulate gene expression in a highly selective manner. 2’-deoxyguanosine-sensing (2’dG) riboswitches represent a unique riboswitch subclass only found in the bacterium Mesoplasma florum and are closely related to adenine- and guanine-sensing riboswitches. The I-A type 2’dG-sensing riboswitch represses the expression of ribonucleotide reductase genes at high cellular concentrations of 2’dG as a result of premature transcription termination.
Increasing evidence within the last decade suggests that transcriptional regulation by riboswitches is controlled kinetically and emphasizes the importance of co-transcriptional folding.2–4 Addition of single nucleotides to nascent transcripts causes a continuous shift in structural equilibrium, where refolding rates are competing with the rate of transcription.5,6
For transcriptional riboswitches, both ligand binding and structural rearrangements within the expression platform are precisely coordinated in time with the rate of transcription. The current thesis investigates the mechanistic details of transcriptional riboswitch regulation using the I-A 2’dG-sensing riboswitch as an example for a riboswitch that acts under kinetic control.