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In this thesis we study strongly correlated electron systems within the Density Functional Theory (DFT) in combination with the Dynamical Mean-Field Theory (DMFT).
First, we give an introduction into the theoretical methods and then apply them to study realistic materials. We present results on the hole-doped 122-family of the iron-based superconductors and the transition-metal oxide SrVO3. Our investigations show that a proper treatment of strong electronic correlations is necessary to describe the experimental observations.
The humanized non-depleting anti-CD4 monoclonal antibody Tregalizumab (BT-061) is able to selectively activate the suppressive function of regulatory T cells and has been investigated up to phase 2b in clinical trials in patients suffering from rheumatoid arthritis (RA).
A pharmacokinetic-pharmacodynamic model, which is based on clinical data from RA and healthy subjects, used the cell surface CD4-down-modulation as marker of the antibodies' activity. This model surprisingly revealed a stronger effect of Tregalizumab in healthy subjects compared to RA patients. This thesis presents a series of experiments performed to understand this phenomenon.
To counteract oxidative stress, which is strongly associated with RA pathophysiology, the organism employs the small oxidoreductase thioredoxin-1 (Trx1). Therefore, augmented expression and secretion of Trx1 was seen in many studies the synovial fluid and plasma of RA patients. Moreover, the binding site of Tregalizumab is in close proximity to a disulfide bond in domain 2 (D2) of CD4, which is a known target for a reduction by Trx1. So, this thesis also evaluated the influence of Trx1 on binding of Tregalizumab to its target CD4.
With the experiments reported herein, it was possible to demonstrate that specific reduction of the D2 disulfide bond of CD4 by Trx1 led to diminished binding of Tregalizumab to recombinant human soluble CD4 (rh sCD4) and membrane-bound CD4 on T cells from a human leukemia cell line and peripheral blood mononuclear cells (PBMC). Moreover, the experiments revealed that this caused changes in the Tregalizumab-induced CD4 signalling pathway via the lymphocyte-specific protein tyrosine kinase p56Lck.
In summary, this thesis provides evidence that high Trx1 levels in RA patients compared to healthy subjects are a potential valid reason for diminished binding of Tregalizumab to CD4-positive T cells and offers an explanation for the observed decreased CD4 down-modulation in RA patients in comparison with healthy subjects. It emphasizes that binding of Tregalizumab is impaired in a particular way in RA patients.
The Hepatitis C virus (HCV) infects more than 170 million individuals worldwide and causes challenging HCV-related diseases. Unfortunately, there is no vaccine available. Therefore, a better understanding of the HCV life cycle is urgently needed to develop more effective and better tolerated therapies.
It has been reported that the secretory pathway plays an essential role for the release of HCV, and the SNARE complexes are a central factor controlling intracellular vesicular trafficking. Recently, our group observed that α-taxilin that binds to free syntaxin 4 prevents the SNARE complex formation and exerts an inhibitory effect on the release of HCV particles. Therefore, it was analyzed whether the t-SNARE protein syntaxin 4 is involved in the HCV life cycle.
An increased intracellular amount of syntaxin 4 was found in HCV-positive cells, while the level of syntaxin 4-specific transcripts was decreased as observed in HCV-positive Huh7.5 cells and in HCV-infected primary human hepatocytes (PHH). Since in HCV-positive cells a significant longer half-life of syntaxin 4 was found, the decreased expression is overcompensated, leading to the elevated amount of syntaxin 4. Overexpression of syntaxin 4 increases the amount of secreted infectious viral particles, while silencing of syntaxin 4 expression decreases the number of released viral particles, which indicates that HCV could use the SNARE-dependent secretory pathway for viral release. Confocal immunofluorescence microscopy and co-immunoprecipitation experiments revealed that syntaxin 4 interacts with HCV core and NS5A. To identify the binding domain, various mutants of syntaxin 4 were generated. Based on these mutants, it was found that the H3 domain of syntaxin 4 interacts with core. These data show that the t-SNARE protein syntaxin 4 is an essential cellular factor for HCV morphogenesis and secretion.
HCV induces autophagy, and in HCV-infected cells a major fraction of the de novo synthesized viral particles is not released but intracellularly degraded. Syntaxin 17 is an autophagosomal SNARE required for the fusion of autophagosomes with lysosomes to form autolysosomes and thereby to deliver the enclosed contents for degradation. Therefore, we aim to investigate whether syntaxin 17 is a relevant factor for the HCV life cycle by regulating the fusion between autophagosomes and lysosomes. It was found that HCV-positive cells possess a decreased amount of syntaxin 17, and HCV reduces the intracellular level of syntaxin 17 by NS5A-mediated interruption of c-Raf signaling, which triggers the syntaxin 17 transcription, and by HCV-dependently induced autophagy. Overexpression of syntaxin 17 decreases the intracellular amount of viral particles and reduces the number of released infectious viral particles by favoring the formation of autolysosomes, in which HCV particles can be degraded. Vice versa, inhibition of syntaxin 17 expression by specific siRNAs results in an elevated amount of intracellular viral particles and increases the number of released viral particles by impaired autophagosome-lysosome fusion. Confocal immunofluorescence microscopy analyses show a fraction of core protein in autophagosomes as stained by lysotracker and the autophagy maker p62. These data identify syntaxin 17 as a novel factor controlling the release of HCV and reveal the autophagosome-autolysosome fusion as an essential step affecting the equilibrium between the release of infectious viral particles and lysosomal degradation of intracellular viral particles.
Taken together, these data identify the t-SNARE proteins syntaxin 4 and syntaxin 17 as essential cellular factors for HCV morphogenesis and secretion.
FUSE Binding Protein 1 (FUBP1) is a transcriptional regulator, which is overexpressed in various cancer entities, including hepatocellular carcinoma (HCC) and colorectal cancer (CRC). It fulfills pro-proliferative and anti-apoptotic functions in cancer cells, resulting in increased proliferation and reduced sensitivity towards apoptotic stimuli.
Previously, camptothecin (CPT) and its clinically used analog 7-ethyl 10hydroxycamptothecin (SN-38) were shown to inhibit FUBP1 in biophysical interaction displacement assays (AlphaScreen; surface plasmon resonance, SPR), and first insights into the cellular effects of FUBP1 inhibition were obtained. CPT and SN-38 are known to potently inhibit topoisomerase 1 (TOP 1), and until today, these inhibitors were thought to be specific for this target. This could be disproved by our FUBP1 binding studies. An open issue, which is addressed in this thesis, was the contribution of FUBP1 inhibition to SN-38-mediated apoptosis apoptosis.
During this thesis, a low micromolar efficacy of CPT/SN-38-induced inhibition of FUBP1 binding to the Far Upstream Sequence Element (FUSE) oligonucleotide of p21 was determined. Furthermore, FUBP1 was for the first time shown to directly interact with a potential FUSE sequence upstream of the transcription start in pro-apoptotic gene BIK. In proof of-principle experiments, an effective inhibition of the binding of FUBP1 to the FUSE BIK DNA by CPT/SN-38 was verified.
One of the main goals of this thesis was to further elucidate the contribution of cellular FUBP1-inhibition by CPT/SN-38 to the anti-cancer potential of these substances. For this purpose, the TOP 1 mutant and TOP 1 wild type colorectal cancer sub-cell lines HCT116 G7 and HCT116 S were used. CPT/SN-38 was shown to induce apoptosis in single and combinatorial treatments with mitomycin c (MMC), independently of the TOP 1 mutation status of the cells. Furthermore, a prominent induction of a FUBP1 target gene signature was observed upon treatment of both cell lines with CPT/SN-38. Consequently, CPT/SN-38 was able to fulfill its anticancer effects in these cells, although TOP 1 could not be the main target in the mutant cell line.
In a second approach to gain indirect evidence for FUBP1 dependent effects of CPT/SN-38, the TOP 1-specific inhibitors topotecan (TTN) and β lapachone (BL) were used for the treatment of HCC and CRC cell lines. Interestingly, the TOP 1 inhibitors TTN and BL exhibited a reduced potency in apoptosis induction compared to the dual (FUBP1 and TOP 1) inhibitor SN-38.
Finally, two independent screens for a specific FUBP1 inhibitor were performed. In the first approach, a small number of structural and functional CPT-derivatives that exhibited a reduced inhibitory potential against TOP 1, were tested for their ability to interfere with the FUBP1/FUSE binding. Two particular indenoisoquinoline derivatives revealed potent in vitro inhibition of FUBP1 with low micromolar IC50 values.
In a second approach, previously identified candidate FUBP1 inhibitors that had been isolated from the Maybridge Hit Finder library served as lead structures for a structure activity relationship (SAR) study of the inhibition of FUBP1 binding to the FUSE oligonucleotide. After two cycles of optimization, a medium-potent FUBP1 inhibitor was obtained that induced effective deregulation of FUBP1 target genes in cell culture experiments.
This thesis describes the adaptation of Acinetobacter species to dry environments with the soil bacterium A. baylyi and the opportunistic hospital pathogen A. baumanii in its focus. The adaptation of A. baylyi and A. baumannii to osmotic stress was investigated. Compatible solutes that were uptaken from the environment or synthesized de novo to cope with the loss of water at high salinity were identified. The corresponding transporters and enzymes involved were characzerized. In addition, the desiccation resistance of A. baumannii was analyzed to elucidate its survival in hospital environments. The usage of compatible solutes during desiccation stress was analyzed and proteins that were produced were identified.
The availability of water is essential for bacterial life and if environmental conditions are awkward, bacteria have to cope with high salinitiy to prevent loss of water. In this thesis it was shown that A. baylyi synthesizes glutamate and mannitol de novo as compatible solutes in response to osmotic stress to balance the osmotic potential. The pathway for mannitol biosynthesis from Fructose-6-Phosphate (F-6-P) via Mannitol-1-Phosphate (Mtl-1-P) was elucidated and the isolation and characterization of a novel type of biofunctional enzyme was described. Interestingly, the unique bifunctional enzyme MtlD, acting as dehydrogenase and phosphatase, mediates both steps of the mannitol biosynthesis pathway. This enzyme catalyzes the reduction of F-6-P to Mtl-1-P with NADPH as reducing equivalent. The dehydrogenase activity of MtlD was salt dependent and the phosphatase activity was dependent on Mg2+ as cofactor. Phylogenetic analyses revealed that MtlD is broadly distributed among other Acinetobacter strains but not in other phylogenetic tribes.
In this thesis it is also described that, besides de novo synthesis of compatible solutes, A. baylyi takes up glycine betaine (GB) or its precursor choline by different transport systems and uses this solutes as osmoprotectants. The uptake of GB occurs via a secondary transporter (ACIAD3460) of the BCCT family. Choline is taken up as precursor and oxidized to GB by two dehydrogenases. The uptake and use of choline as GB precursor involves two transporters, whose genes are encoded in the bet cluster (BetT1, BetT2), two dehydrogenases (BetA, BetB) and a regulatory protein (BetI). Both transporters differ from each other in structure and function: BetT1 is osmo-independent and active independently of osmotic stress. BetT2 contains - in contrast to BetT1 - a long C-terminal domain for osmo-sensing and its activity highly increases in the presence of high osmolarity. The oxidation of choline occurs independently of the osmolarity of the medium but in the absence of salt stress, GB is exported. In contrast, in the presence of high salinity, GB is accumulated in the cytoplasm to balance the osmotic potential in order to prevent loss of water. The regulation of both transporters, the uptake of choline independently of the osmolarity and the export of GB under isoosmotic conditions are regulated by the transcriptional regulator BetI.
A. baumannii ATCC 19606 was also shown to cope with high salinity. Analogously to A. baylyi, A. baumannii ATCC19606 synthesizes glutamate and mannitol de novo in response to osmotic stress. The genes for the synthesis of these compatible solutes are identical to those found in A. baylyi. This suggests that the solute biosynthesis pathways of A. baumannii and A. baylyi are identical. A. baumannii was also able to take up GB and choline in response to osmotic stress and growth at high salinity was restored upon addition of GB and its precursor choline. The bet cluster was also present in the genome A. baumannii and also contains the two different choline transporters BetT1 and BetT2.
Our suggestion that choline or GB or the utilization of phosphatidylcholine as carbon source led to an increase in the survival under desiccation stress was not confirmed. However, 2D analysis of proteins produced during desiccation stress in A. baumannii led to elevated amounts of proteins implicated in biofilm formation, regulation, cell morphology and general stress response, such as Hsp60 or superoxide dismutase, both might play a role in general stress protection.
Protein synthesis is a central process within every living cell, where information embodied in the nucleotide sequence of the mRNA is translated into the primary sequence of proteins. The translation procedure comprises four steps: initiation, elongation, termination, and recycling. Ribosome recycling orchestrated by the ATP‐binding cassette (ABC) protein ABCE1, renders mRNA translation into a cyclic process, connecting termination with re initiation. In Archaea and Eukarya, the ABC protein ABCE1 catalyzes ribosome recycling by splitting the ribosome (80S/70S) into the small 40S/30S and large 60S/50S subunits, providing them for the next translation round.
The ABC‐type ATPase one of the most conserved proteins, present in all Archaea and Eukarya, but not in Bacteria, is essential for life in all organisms examined so far. ABCE1 was initially identified as RNase L inhibitor (Rli1), involved in the antiviral RNA immunity, and as host protein 68 (HP68) playing a role in HIV capsid assembly. However, the strong sequence conservation of ABCE1 points towards a more fundamental function within cell homeostasis, which was found by its involvement in various translation processes. ABCE1 turned out to be the major ribosome recycling factor indispensable for life in Eukarya and Archaea, being involved in canonical translation, mRNA surveillance, ribosome biogenesis, and translation initiation.
Recent functional and structural data provided first insights into the mechanism of ABCE1 in ribosome recycling. The nucleotide‐binding domains (NBDs) sandwich two ATP molecules in the NBD1‐NBD2 interface causing an NBD engagement, which is released upon ATP hydrolysis. In case of ABCE1, this ATP‐dependent tweezer‐like motion of the NBDs transfers mechanical energy to the ribosome and tears the subunits apart. The FeS‐cluster domain may swing out of the NBD cleft into the inter‐subunit space of the ribosome, which drives the subunits apart either directly or via the bound a/eRF1. Hence, the subunits are released and the post‐splitting complex (PSC, 40S/30S∙ABCE1∙ATP) is available for re‐initiation events, presumably occurring via the known interactions of ABCE1with initiation factors.
One of the most crucial aspects of this model is the nucleotide‐dependent conformational switch of ABCE1, which drives ribosomal subunit splitting. However, the conformational states, which ABCE1 undergoes during ribosome recycling, including their mechanistic importance for its diverse functions, remain unknown. Further, the exact role and movement of the essential FeScluster domain during ribosome recycling are not yet understood. Additional, it remains elusive where ABCE1 is bound in the post‐splitting complex and how the splitting mechanism is regulated concerning the asymmetric NBDs and the coupling of nucleotide binding with NBD closing and ATP hydrolysis.
Thus, in order to monitor the conformational dynamics of the ribosome recycling factor ABCE1 two complementing methods in structural biology, namely single‐molecule based Förster resonance energy transfer (smFRET) and pulsed electron‐electron double resonance (PELDOR) spectroscopy were applied.
Single‐molecule FRET as an integrated biophysical approach based on Förster resonance energy transfer and single‐molecule detection was used to understand the fundamental molecular principles of ABCE1. Contrary to the anticipated two‐state model of ABC proteins, it was shown in this thesis that both nucleotide‐binding sites of ABCE1 are always in a dynamic equilibrium between conformational states with distinct properties: open, intermediate, and closed. The equilibrium in the two nucleotide‐binding sites is distinctly affected when ABCE1 interacts with ribosomal subunits and nucleotides. While ABCE1 can adopt all three conformational states in its free or 30S bound situation, the closed state has the highest affinity for 30S subunit. Further, dissociation of ABCE1 from the small ribosomal subunit, a step that completes the recycling process, is followed by the opening of the NBSs. Hence, the current findings have important implications not only for ribosome recycling but represent a new paradigm for the molecular mechanisms of twin‐ATPases.
The complementing PELDOR measurements provide the advantage of high distance precision and reliability studying macromolecular complexes. Distance distributions of a number of ABCE1 variants even bound to the 1‐MDa post‐splitting complex (30S∙ABCE1∙AMP‐PNP), composed of the 16S rRNA, 28 ribosomal proteins, and ABCE1, was analyzed. Thus, the available crystal structures of ABCE1 in the open state were validated, since all distances of ABCE1 measured in this study perfectly correspond to this crystallized state. Unfortunately, ABCE1 could not be trapped in the closed state under the experimental conditions applied, although plenty different approaches to stabilize this state were performed.
In the second part of this study the architecture yet unknown of the 1‐MDa post splitting complex (40S/30S∙ABCE1∙ATP), concerning especially the ABCE1 binding site and its interactions with translational proteins, was probed by a method, which combines chemical cross linking with mass‐spectrometry (XL‐MS). Following this approach, it was demonstrated that ABCE1 remains bound at the translational GTPase‐binding site after ribosome splitting, contacting the S24e protein of the small subunit. The platform for the intensive contacts to the small ribosomal subunit is thereby provided by the unique helix‐loop‐helix motif of ABCE1. Notably, the FeScluster domain of ABCE1 undergoes a large rotational and translational rearrangement towards the small ribosomal subunit S12 upon nucleotide‐dependent closure of the NBDs. Thus, a key complex in the translational cycle, resembling the link between translation initiation and ribosome recycling processes, was reconstituted and structurally analyzed.
In view of the diverse functionalities of RNA, the search for tools suitable for regulating and understanding RNA grows continuously. Dysfunction of RNA controlled processes can lead to diseases, calling for external regulation mechanisms – a difficult task in view of the complexity of biological systems. One of the recently developed methods that aim to systematically control RNA relates to photoregulation. Here, the RNA functions are triggered by photochromic molecules – for example, azobenzene or spiropyran – which are bound either covalently or non-covalently to the target RNA. This is a flexible approach, which can be improved by using suitably substituted chromophores. However, many issues regarding the details of photocontrol are still open. A detailed understanding of the mechanism of photocontrol is therefore of crucial importance.
The present thesis explores theoretical approaches to the photocontrol of RNA, focussing upon azobenzene chromophores covalently bound to RNA. The aim of the thesis is to characterize, at a molecular level, the effect of trans-to-cis isomerization of the azobenzene chromophore on RNA, and thus understand the mechanism of RNA unfolding triggered by azobenzene isomerization. In particular, we attempt to answer the following questions:
How does azobenzene isomerization happen in an RNA environment, i.e., how is
the isomerization influenced by the local RNA environment?
Conversely, how is RNA dynamics, on a longer time scale, affected by azobenzene attachment and photoisomerization?
Further, can regulation be enhanced by substituted azobenzenes? And, does simulation yield a picture that is consistent with experiment?
Due to the very different times scales of azobenzene isomerization (femtoseconds to picoseconds) and the much slower RNA response (nanoseconds to milliseconds), complementary techniques have been chosen: (i) hybrid quantum-classical approaches, i.e., on-the-fly Quantum Mechanics/Molecular Mechanics (QM/MM), to characterize the isomerization and RNA response on an ultrafast time scale, and (ii) molecular dynamics with enhanced sampling techniques, in particular, Replica Exchange MD (REMD), to explore longer time scales where the effect of RNA unfolding becomes manifest. Furthermore, substituent effects on azobenzene were separately investigated, in collaboration with two experimental groups.
The first part of this thesis is focused on the conformational influence of azobenzene on a small RNA hairpin on longer time scales using REMD simulations. In accordance with experiment, it is found that both the trans and cis form of azobenzene destabilize the RNA system. Trans azobenzene stays stacked in the double strand, whereas the cis form flips out of the RNA. These stacking interactions are the main reason why a trans azobenzene-RNA-complex is more stable than a cis-azobenzene-RNA-complex. Furthermore, the loop region of the RNA hairpin is highly destabilized by the intercalation of azobenzene.
In the second part, on-the-fly QM/MM simulations of the same azobenzene substituted hairpin are undertaken. These simulations use a surface hopping (SH) algorithm in conjunction with hybrid QM/MM electronic structure calculations to give a complete picture of the isomerization process on a picosecond time scale. It is shown that, due to the constraints of the RNA environment, the isomerization time of the azobenzene chromophore is significantly increased (from 300 femtoseconds in the gas phase to around 20 picoseconds in the RNA environment), and the isomerization yield is low. To the best of our knowledge, these are the first QM/MM simulations reported for azobenzene in a nucleic acid environment.
In the third and final part of this thesis, the properties of substituted azobenzenes have been explored, in collaboration with two experimental groups at the department. In particular, para- and meta-hydroxy substituted azobenzenes were suggested as improved photoswitches for the photoregulation of RNA, but spectroscopic investigations showed that isomerization was inefficient in some of the investigated species. Therefore, we investigated the photoisomerisation pathway of the keto/enol-form of para- and meta-hydroxy-azobenzenes by Time-Dependent Density Functional Theory (TDDFT) calculations. These calculations show that the competing keto/enol-tautomerism can result in an unstable cis form, making these substituted chromophores unsuitable as photoswitches.
Overall, the present thesis has contributed to obtaining a molecular-level understanding of photocontrol in azobenzene substituted RNAs, showing that theory and simulations can provide useful guidance for new experiments.
The transporter associated with antigen processing (TAP) is a heterodimeric ATP-binding cassette (ABC) transport complex, which selects peptides for export into the endoplasmic reticulum (ER) and subsequent loading onto major histocompatibility complex class I (MHC I) molecules to trigger adaptive immune responses against virally or malignantly transformed cells. Due to its pivotal role in adaptive immunity, TAP is a target for infectious diseases and malignant disorders, such as bare lymphocyte syndrome type I and cancer. A detailed knowledge about the TAP structure and transport mechanism is fundamental for the development of therapies or drugs against such diseases, but numerous aspects are insufficiently determined to date. The aim of this PhD thesis was to elucidate several structural details of TAP using powerful biochemical and biophysical methods and thereby to contribute to the understanding of the translocation machinery functionality.
High protein yields, an efficient isolation from the lipid environment and subsequent purification of a stoichiometric, stable, and functional TAP complex are prerequisites to get detailed insights into TAP functionality. The natural product digitonin is typically used as detergent to isolate TAP, but suffered from fluctuating purity and high costs. The novel detergent GDN was selected from a number of potential detergents upon their ability to isolate and purify TAP overcoming the limitations of digitonin without compromising on functional integrity. State-of-the-art biophysical techniques, such as solid-state nuclear magnetic resonance (NMR), require highly concentrated protein samples. A new and mild procedure to concentrate TAP was established within this thesis. Freeze drying is superior to conventional concentration techniques, such as ultrafiltration, resulting in TAP inactivation and aggregation already at concentrations of 10 mg/mL. This new procedure enables stabilizing TAP in a condensed glycerol matrix and to concentrate the transport complex up to 30 mg/mL active transporter. The functional integrity of the freeze-dried TAP complex was verified by determining equilibrium dissociation constants, peptide dissociation and ATP-hydrolysis rates as well as long-term stabilities identical to untreated TAP. The combined application of the detergent GDN and the freeze drying procedure facilitates the cost-efficient isolation of functional and highly concentrated TAP and enables to study the structure and mechanism of the peptide transporter TAP using modern analyses methods.
Information on peptide-TAP interactions at atomic level have not been obtained so far. This lack of knowledge hampered the mechanistic understanding of the initial steps of substrate translocation catalyzed by TAP. Dynamic nuclear polarization (DNP) enhanced magic angle spinning (MAS) solid-state NMR on highly concentrated TAP samples prepared with the freeze-drying procedure was used within this thesis to study this challenging membrane protein-substrate complex. The affinity and specificity of peptide binding by TAP are mediated by multiple recognition sites in the N- and C-terminal regions. Side-chains of positions 1, 3, and 9 are most substantially affected upon binding to TAP, revealing recognition principles of the translocation machinery. The nonamer peptide binds to TAP in an extended conformation with an N-to-C terminus distance of ~2.5 nm. Molecular docking revealed that the peptide substrate is locked with its N and C termini between TAP1 and TAP2 and adopts a tilted pose with respect to the membrane plane. The identified contact sites of TAP are consistent with results from earlier crosslinking and mutational analyses on the TAP complex.
The inadequate structure determination and insufficient knowledge about the dynamics of substrate translocation impedes a detailed comprehension of the TAP transport mechanism. Advanced biophysical methods, such as pulsed electron paramagnetic resonance (EPR) or single-molecule Förster resonance energy transfer (FRET), enable to locate the peptide-binding pocket and to elucidate dwell-times, conformational states and dynamics within the translocation cycle of TAP. The specific introduction of spin or fluorescent labels via single cysteines for such studies requires a cysteine-less TAP complex. The endogenous cysteine 213 in TAP2 remained to create a pseudo Cys-less TAP complex within this thesis due to its altered substrate repertoire when mutated to serine as shown in previous studies. Latter complex was used to introduce single-Cys mutations in the cytosolic extensions of transmembrane helices of TAP1. Their functional integrity with respect to peptide binding and translocation was comparable to pseudo Cys-less TAP. All pseudo single cysteines were efficiently labeled, but unintentionally C213TAP2 was labeled as well and TAP concomitantly inactivated. These unsatisfactory initial experiments required the generation of a functional, entirely Cys-less TAP transporter within this thesis. Therefore, C213TAP2 was replaced by all 19 proteinogenic amino acids. All analyzed mutants were capable to bind a high-affinity peptide of TAP, but with varying affinities and binding capacities. The replacement of C213 by isoleucine enabled the generation of a cysteine-less TAP complex with functional characteristics similar to the wild-type transporter and will promote the elucidation of the translocation mechanism of the peptide transporter TAP in future studies using pulsed EPR and single-molecule FRET.
Magnetoencephalography (MEG) measures neural activity non-invasively and at an excellent temporal resolution. Since its invention (Cohen, 1968, 1972), MEG has proven a most valuable tool in neurocognitive (Salmelin et al., 1994) and clinical research (Stufflebeam et al., 2009; Van ’t Ent et al., 2003). MEG is able to measure rapid changes in electrophysiological neural signals related to sensory and cognitive processes. The magnetic fields measured outside the head by MEG directly reflect the cortical currents generated by the synchronised activity of thousands of neuronal sources. This distinguishes MEG from functional magnetic resonance imaging (fMRI), where measurements are only indirectly related to electrophysiological activity through neurovascular coupling...
Soil fungal communities are an essential element in the terrestrial ecosystem, however their response to ongoing anthropogenic climate change is currently poorly understood. Fungi are one of the most abundant groups of microbes in soil, they are mainly responsible for the decomposition of organic matter (Baldrian et al., 2012; Buée et al., 2009). By binding carbon in soil, fungi thus maintain an important role in the global carbon cycle (Bardgett et al., 2008). Future climates are likely to influence the communities of belowground microbial organisms (Castro et al., 2010; Deacon et al., 2006). However, how these communities are affected in their diversity, composition, and function after environmental perturbation is insufficiently known.
Molecular techniques using high-throughput sequencing are presently revolutionizing the analysis of complex communities, such as soil fungi. High-throughput metabarcoding enables the recovery of DNA sequence data directly from environmental samples, and DNA sequences from entire communities present in these samples can be simultaneously recovered through massively parallel sequencing reactions (Bik et al., 2012; Taberlet et al., 2012b). This results in more accurate estimation of diversity and community composition and thus provides unprecedented insight into cryptic communities (Lindahl and Kuske, 2014). Yet, challenges associated with these novel techniques include the bioinformatic processing, and the ecological analyses of the large amount of sequence data generated. Most biologists without explicit training in bioinformatics spend a fair amount of time learning how to filter raw sequence data, and customize bioinformatics pipelines specific to their project. To improve the quality of data treatment, and decrease the time needed for the analyses, it is desirable to have bioinformatics pipelines that are easy to use, well explained to researchers not trained in bioinformatics, and adaptable to individual research needs...