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Spinocerebellar ataxia type 2 (SCA2) is an autosomal dominant neurodegenerative movement disorder caused by expansion of CAG repeats in the ATXN2 gene beyond 33 units, while healthy individuals carry 22-23 repeats. First symptoms of SCA2 include uncoordinated movement, ataxic gait and slowing of the saccadic eye movements in line with the early pronounced atrophy of cerebellum, spinal cord and brainstem. Cerebellar Purkinje cells and spinal cord motor neurons are the most affected cells from ATXN2 expansions. Later on, patients manifest distal amyotrophy, problems in breathing and swallowing, depression and cognitive decline caused by widespread degeneration throughout the brain. The striking loss of mass in the brain, due to severe myelin fat atrophy, is accompanied by a similar reduction in the peripheral fat stores. After the devastating progression of disease, the severity and duration of which depends on the CAG repeat size, genetic background and environmental factors, patients succumb to SCA2 mostly because of respiratory failure at the terminal stage. Larger repeat sizes lead to an earlier manifestation of the disease and a more rapid progression. Aside from SCA2, intermediate-length and short pathogenic CAG expansions in ATXN2 between 26-39 repeats significantly increase the risk of developing other neurodegenerative disorders, such as amyotrophic lateral sclerosis (ALS), fronto-temporal lobar dementia (FTLD) or Parkinson plus tauopathies like progressive supranuclear palsy (PSP) in various cohorts across the world.
Ataxin-2 (ATXN2) is a ubiquitously expressed cytosolic protein most famous for its involvement in neurodegenerative disease caused by the expanded poly-glutamine (polyQ) domain corresponding to a genomic (CAG)n tract. This N-terminal polyQ domain has no known function, other than increasing the aggregation propensity of mutant ATXN2 and facilitating interaction with other polyQ containing proteins, leading to their sequestration. The progressive accumulation of ATXN2 into cytosolic foci, and also that of its interaction partners over time, underlies the molecular pathomechanism. Next to polyQ domain, ATXN2 also contains a Like-Sm domain (Lsm), an Lsm-associated domain (LsmAD), multiple proline-rich domains (PRD) and a Poly(A)-Binding-Protein (PABP)-interacting motif (PAM2).
Through its Lsm/LsmAD domains, ATXN2 directly binds to a large number of transcripts, regulating their quality and translation rate. In a similar fashion, through its direct interaction with PABP via PAM2 motif, ATXN2 indirectly modifies the fate of even larger number of transcripts and global translation. Several PRDs scattered across the protein help ATXN2 associate with growth factor receptors and other endocytosis factors, modulating nutrient uptake and downstream signaling.
ATXN2 is a stress response factor. Therefore, its involvement in nutrient uptake plays a crucial part in cell’s capability to overcome non-permissive conditions. Upon nutrient deprivation, oxidative stress, proteotoxicity, heat stress or Ca2+ imbalance, ATXN2 relocalizes into cytosolic ribonucleoprotein particles known as stress granules (SGs), together with PABP, several eukaryotic translation initiation factors, many other RNA-binding proteins (RBP) with their target transcripts and the small ribosomal subunit. Collectively, they modulate the stability of the trapped transcripts, favoring the maturation and translation of IRES-dependent stress response proteins instead, according to the specific need. Many RBPs interact either directly or in an RNA-dependent manner in the SGs, and due to the large number of ALS-causing mutations identified in them (such as TDP-43, FUS, TIA-1, hnRNPA2/B1), SGs became a hot topic in neuropathology. Acute SGs serve to halt translation and growth, and to spend energy only for survival until stress disappears. However, chronic SG assembly eventually activates apoptotis leading to cell death. While the polyQ expansions in ATXN2 enhance SG stability, reduce their dissociation rate after stress, and lead to aberrant post-translational modifications of other SG components like TDP-43, complete loss of ATXN2 delays SG formation and results in easily dissolvable foci.
Most of the stressors that induce SG formation eventually converge on energetic deficit. Therefore, it is logical that the ultimate task of SGs is to stop further growth when it cannot be afforded. In yeast, the molecular mechanism underlying this growth arrest was explained as sequestration of the master growth regulator complex, Target-of-Rapamycin Complex 1 (TORC1), into SGs in an ATXN2-dependent manner. The repressor effect of ATXN2 on mammalian TORC1 (mTORC1) and global protein translation had already been documented in earlier studies; complete loss of ATXN2 function in knock-out mouse (Atxn2-KO) resulted in mTORC1 hyperactivity and transcriptional upregulation of multiple ribosomal subunits indicating an increased need for these machines. ...
Evidence is increasingly pointing towards a significant global decline in biodiversity. The drivers of this decline are numerous, including habitat change and overexploitation, rapid deforestation, pollution, exotic species and disease, and finally climate change as an emerging driver of biodiversity change (Nakamura, et al., 2013; Hancocks, 2001; Pereira, Navarro & Martins, 2012). Raising public awareness of the need to conserve biological diversity is essential to safeguard the richness of life forms all over the world (Lindemann-Matthies, 2002). In this regard, institutions such as science museums, zoos and aquariums have the potential to play an important role (Rennie & Stocklmayer, 2003). Especially, zoos can provide a productive learning environment (Miles & Tout, 1992), facilitating the promotion of public conservation awareness and the adoption of pro-environmental behaviours that would reduce negative human impacts on biodiversity (Barongi, et al., 2015).
Based on these concepts, my study contributes to the developing field of visitor studies. Taking as reference non-zoo visitors and zoo visitors, I have focused on reviewing some aspects of conservation education, such as people's awareness of conservation, people's interest in animals and people's feelings towards animals and attitudes towards zoos. The study identified differences between non-regular and regular zoo visitors in interests in animals, as well as visitor attitudes towards conservation issues and zoos. Therefore, the present study indicated that positive emotional reactions and, in particular, a perceived sense of connection to the animal were linked and depended on the frequency of zoo visits. It was as well remarkable, that conservation awareness was influenced by the interest in animals, the interest in visiting zoos, the attitudes towards these institutions, and the age and the country of origin. All these variables had a greater effect in the conservation consciousness of the participants. Additionally interestingly, the main reason for visiting zoos in every country was to learn something about animals. This highlights the educational role of zoos and broadly supports the idea that people want to visit zoos to learn something about animals, in turn facilitating pro-conservation learning and changes in attitude. They are uniquely positioned to interact with visitors, communities, and society and to contribute by providing an informative and entertaining environment. Visiting zoos could led to contribute to promoting animal connectedness and interest in species.
This Dissertation deals with the development of FAIR-relevant X-ray diagnostics based on the interaction of lasers and particle beams with matter. The associated experimental methods are supposed to be employed in the HIHEX-experiments in the HHT-cave of the GSI Helmholtz Center for Heavy-Ion Research GmbH (GSI) in Phase-0 and in the APPA-cave at the Facility for Antiproton and Ion Research in Darmstadt, Germany.
Diagnostic of high aerial density targets that will be used in FAIR experiments demands intense and highly penetrating X-ray sources. Laser generated well-directe relativistic electron beams that interact with high Z materials is an excellent tool for generation of short-pulse high luminous sources of MeV-gammas.
In pilot experiments carried out at the PHELIX laser system, GSI Darmstadt, relativistic electrons were produced in a long scale plasma of near critical electron density (NCD) by the mechanism of the direct laser acceleration (DLA). Low density polymer foam layers preionised by a well-defined nanosecond laser pulse were used as NCD targets. The analysis of the measured electron spectra showed up to 10- fold increase of the electron "temperature" from T_Hot = 1–2 MeV, measured for the case of the interaction of 1–2 ×10^19 Wcm^(−2) ps-laser pulse with a planar foil, up to 14 MeV for the case when the relativistic laser pulse propagates through the by a ns-pulse preionised foam layer. In this case, up to 80–90 MeV electron energy was registered. An increase of the electron energy was accompanied by a strong increase of the number of relativistic electrons and well-defined directionality of the relativistic electron beam measured to be (12 ±1)° (FWHM). This directionality increases the gamma flux on target by far compared to the soft X-ray sources.
Additionally to laser based active diagnostics, passive techniques involving inherent X-ray fluorescence radiation of projectile and target emitted during heavy-ion target interaction can be used to measure the ion beam distribution on shot. This information is of great importance, since the target size is chosen to be smaller than the beam focus in order to ensure homogeneous heating of the HIHEX-target by the ion beam. High amounts of parasitic radiation and activation of experimental equipment is expected for experiments at the APPA-cave. For this reason, all electronic devices must be placed at a safe distance to the target chamber. In order to transport the signal over a large distance, the X-ray image of the target irradiated by heavy-ions has to be converted into an optical one.
For these purposes, the X-ray Conversion to Optical radiation and Transport (XCOT)-system was developed in the frame of a BMBF-project and commissioned in two beamtimes at the UNILAC, GSI during this work.
In experiments, we observed intense radiation of target atoms (K-shell transitions in Cu at 8–8.3 keV and L-shell transition in Ta) ionised in collisions with heavy ions as well as Doppler-shifted L-shell transitions of Au-projectiles passing through targets. This radiation can be used for monochromatic (dispersive elements like bent crystals) or polychromatic (pinhole) 2D X-ray mapping of the ion beam intensity distribution in the interaction region during the beam-target interaction. We measured the efficiency of the X-ray photon production depending on the target thickness and the number of ions passing through the target. The spatial resolution of the XCOT-system based on the multi-pinhole camera was measured to be (91±17) μm for the image magnification factor M = 2. It was considerably improved by application of a toroidally bent quartz crystal and reached 30 μm at M = 6. This resolution is optimal to image the distribution of a 1mm in diameter ion beam. As next step, the XCOT-system will be tested during the SIS18 beam-time at the HHT-experimental area.
The application of natural products (NPs) as drugs and lead compounds has greatly improved human health over the past few decades. Despite their success, we still need to find new NPs that can be used as drugs to combat increasing drug resistance via new modes of action and to develop safer treatments with less side effects.
Entomopathogenic bacteria of Xenorhabdus and Photorhabdus that live in mutualistic symbiosis with nematodes are considered as promising producers of NPs, since more than 6.5% of their genomes are assigned to biosynthetic gene clusters (BGCs) responsible for production of secondary metabolites. The investigation on NPs from Xenorhabdus and Photorhabdus can not only provide new compounds for drug discovery but also help to understand the biochemical basis involved in mutualistic and pathogenic symbiosis of bacteria, nematode host and insect prey.
Nonribosomal peptides (NRPs) are a large class of NPs that are mainly found in bacteria and fungi. They are biosynthesized by nonribosomal peptide synthetases (NRPSs) and display diverse functions, representing more than 20 clinically used drugs. Although a large number of NRPs have been identified in Xenorhabdus and Photorhabdus, the advanced genome sequencing and bioinformatic analysis indicate that these bacteria still have many unknown NRPS-encoding gene clusters for NRP production that are worth to explore. Therefore, this thesis focuses on the discovery, biosynthesis, structure identification, and biological functions of new NRPs from Xenorhabdus and Photorhabdus.
The first publication describes the isolation and structure elucidation of seven new rhabdopeptide/xenortide-like peptides (RXPs) from X. innexi, incorporating putrescine or ammonia as the C-terminal amines. Bioactivity testing of these RXPs revealed potent antiprotozoal activity against the causative agents of sleeping sickness (Trypanosoma brucei rhodesiense) and malaria (Plasmodium falciparum), making them the most active RXP derivatives known to date. Biosynthetically, the initial NRPS module InxA might act iteratively with a flexible methyltransferase activity to catalyze the incorporation of the first five or six N-methylvaline/valine to these peptides.
The second publication focuses on the structure elucidation of seven unusual methionine-containing RXPs that were found as minor products in E. coli carrying the BGC kj12ABC from Xenorhabdus KJ12.1. To confirm the proposed structures from detailed HPLC-MS analysis, a solid-phase peptide synthesis (SPPS) method was developed for the synthesis of these partially methylated RXPs. These RXPs also exhibited good effects against T. brucei rhodesiense and P. falciparum, suggesting RXPs might play a role in protecting insect cadaver from soil-living protozoa to support the symbiosis with nematodes.
The third publication presents the identification of a new peptide library, named photohexapeptide library, which occurred after the biosynthetic gene phpS was activated in P. asymbiotica PB68.1 via promoter exchange. The chemical diversity of the photohexapeptides results from unusual promiscuous specificity of five out of six adenylation (A) domains being an excellent example of how to create compound libraries in nature. Furthermore, photohexapeptides enrich the family of the rare linear D-/L-peptide NPs.
The fourth publication concentrates on the structure elucidation of a new cyclohexapeptide, termed photoditritide, which was produced by P. temperata Meg1 after the biosynthetic gene pdtS was activated via promoter exchange. Photoditritide so far is the only example of a peptide from entomopathogenic bacteria that contains the uncommon amino acid homoarginine. The potent antimicrobial activity of photoditritide against Micrococcus luteus implies that photoditritide can protect the insect cadaver from food competitor bacteria in the complex life cycle of nematode and bacteria.
The last publication reports a new family of cyclic lipopeptides (CLPs), named phototemtides, which were obtained after the BGC pttABC from P. temperata Meg1 was heterologously expressed in E. coli. The gene pttA encodes an MbtH protein that was required for the biosynthesis of phototemtides in E. coli. To determine the absolute configurations of the hydroxy fatty acids, a total synthesis of the major compound phototemtide A was performed. Although the antimalarial activity of phototemtide A is only weak, it might be a starting point towards a selective P. falciparum compound, as it shows no activity against any other tested organisms.
Over the last decade, cryo-EM has developed exponentially due to improvements in both hardware (“machine”-based) and software (“algorithm”-based). These improvements have pushed the best achievable resolutions closer to atomic level, bridging “gaps” not covered by other biophysical techniques, and allowing more difficult biological questions to be addressed. Thus, this PhD project was designed and constructed to apply cryo-EM to answer biological questions, while allowing simultaneous cryo-EM method development.
The biological focus of this research is pentameric ligand-gated ion channels (pLGICs), specifically the serotonin receptor type-3 receptor (5HT3R), which also belongs to the Cys-loop receptor family. 5HT3R plays an important role in fast synaptic signal transduction in response to agonist and antagonist binding. Binding to its native ligand results in opening of the channel at the transmembrane domain, allowing cations to pass through, resulting in membrane depolarization and conversion of the chemical signal into an electrical one.
This work consisted mainly of two specific aims. One was focused on conformational investigation of 5HT3R in its ligand-bound open conformation, using cryo-electron microscopy (cryo-SPA), in order to understand the gating mechanism upon ligand activation. The other one was to combine SPA with cryo-ET and STA to push the resolution limitation of conventional cryo-ET and STA workflows.
In the end, three different cryo-EM conformations of membrane-embedded 5HT3R were resolved using cryo-SPA, two structures in resting closed forms, one C5-symmetric and one C1-asymmetric, and one serotonin-bound open form. These three structures presented a number of novel features related to the transition of the receptor to its ion-conductive state. Specifically, the serotonin-bound receptor shows asymmetric opening, which was speculated to occur via an intermediate asymmetric Apo state. In addition to the cryo-SPA work, application of cryo-ET and STA to the study of 5HT3R in native vesicles is described in this thesis. Additional work on methods development, focused on combining SPA and STA techniques, along with preliminary results on tobacco mosaic virus are also detailed and discussed.
Moreover, previously unreported asymmetric arrangements of the subunits of the homopentameric 5HT3R around the pore axis were revealed. The asymmetric open state is stabilized by phospholipids inserted at the interface between subunits, at a site well-documented for the binding of allosteric pLGIC modulators. These results not only give structural support to a large body of functional data on the effects of lipids on the function of this receptor family, but also provide structural guidance for future studies in this field. Meanwhile, the SPA-STA combined methods developed during the course of this work have the potential to help resolve higher resolution tomography-based structures, which would benefit researchers seeking to do in-situ-based structural studies.
Diese Thesis befasst sich mit dem Problem korrelierter Elektronensysteme in realen Materialien. Ausgangspunkt hierbei ist die quantenmechanische Beschreibung dieser Systeme im Rahmen der sogenannten Kohn-Scham Dichtefunktionaltheorie, welche die Elektronen der Kristallsysteme als effektiv nicht-wechselwirkende Teilchen beschreibt.
Während diese Modellierung im Falle vieler Materialklassen erfolgreich ist, unterscheiden sich die korrelierten Elektronensysteme dadurch, dass der kollektive Charakter der Elektronendynamik nicht zu vernachlässigen ist.
Um diese Korrelationseffekte genauer zu untersuchen, verwenden wir in dieser Arbeit das Hubbard-Modell, welches mit der projektiven Wannierfunktionsmethode aus der Kohn-Scham Dichtefunktionaltheorie konstruiert werden kann.
Das Hubbard-Modell umfasst hierbei nur die lokale Elektron-Elektron-Wechselwirkung auf einem Gitter. Auch wenn das Modell augenscheinlich sehr simpel ist, existieren exakte Lösungen nur in bestimmten Grenzfällen. Dies macht die Entwicklung approximativer Ansätze erforderlich, wobei die Weiterentwicklung der sogenannten Two-Particle Self-Consistent Methode (TPSC) eine zentrale Rolle dieser Arbeit einnimmt.
Bei TPSC handelt es sich um eine Vielteilchenmethode, die in der Sprache funktionaler Ableitungen und sogenannter conserving approximations hergeleitet werden kann.
Der zentrale Gedanke dabei ist, den effektiven Wechselwirkungsvertex als statisch und lokal zu approximieren. Dies wiederum erlaubt die Bewegungsgleichung des Systems
erheblich zu vereinfachen, sodass eine numerische approximative Lösung des Hubbard-Modells möglich wird. Vorsetzung hierbei ist nur, dass sich das System in der normalleitenden Phase befindet und die bei Phasenübergängen entstehenden Fluktuationen nicht zu groß sind.
Während diese Methode ursprünglich von Y. M. Vilk und A.-M. Tremblay für das Ein-Orbital Hubbard-Modell entwickelt wurde, stellen wir in dieser Arbeit eine Erweiterung auf Viel-Orbital-Systeme vor.
Im Falle mehrerer Orbitale treten in der TPSC-Herleitung einzelne Komplikationen auf, die mit weiteren Approximationen behandelt werden müssen. Diese werden anhand eines einfachen Zwei-Orbital Modell-Systems diskutiert und die TPSC-Ergebnisse werden darüber hinaus mit den Ergebnissen der etablierten dynamischen Molekularfeldnährung verglichen.
In diesem Zusammenhang werden auch mögliche zukünftige Erweiterungen bzw. Verbesserungen von TPSC diskutiert.
Ein weiterer wichtiger Aspekt ist die Anwendung von TPSC auf reale Materialien.
In diesem Zusammenhang werden in dieser Arbeit die supraleitenden Eigenschaften der organischen K-(ET)2X Systeme untersucht. Hierbei lassen die TPSC-Resultate darauf schließen, dass das populäre Dimer-Modell, welches zur Beschreibung dieser Materialien herangezogen wird, nicht genügt um die experimentell bestimmten kritischen Temperaturen zu erklären und dass das komplexere Molekülmodell weitere exotische supraleitende Lösungen zulässt.
Schließlich untersuchen wir außerdem die elektronischen Eigenschaften des eisenbasierten Supraleiters LiFeAs und diskutieren inwieweit nicht-lokale Korrelationseffekte, welche durch TPSC aufgelöst werden können, die experimentellen Daten reproduzieren.
Alzheimer’s disease (AD) is the major cause of dementia. It is characterized by the accumulation of abnormal proteins (amyloid-β plaque and neurofibrillary tangles) leading to loss of synapses, dendrites, neurons, memory and cognition. Sporadic late-onset AD is the major type of AD characterized by unclear etiology and a lack of disease-modifying therapy. To understand this disease, an alternative AD hypothesis has been proposed: AD may resemble diabetes in the brain or “diabetes type 3”. This hypothesis is supported by the fact that (1) brain glucose hypometabolism precedes AD clinical symptoms and (2) diabetes increases the risk of AD. To test this hypothesis, wild-type rats receiving intracerebroventricular administration of streptozotocin (icv-STZ) were used as a model. Streptozotocin (STZ) is a glucosamine-nitrosourea compound commonly used to induce experimental diabetes by peripheral administration. A similar pathological mechanism to peripheral STZ is then proposed to explain icv-STZ toxicity: insulin receptor signaling impairment results in glucose hypometabolism leading to cognitive deficits.
Objective: Icv-STZ model seems promising as a toxin-induced, non-transgenic AD model with the possibility to connect AD and diabetes mellitus (DM), one of the risk factors for AD. However, the mechanisms of how icv-STZ induced AD-like symptoms are unclear. Therefore, using microdialysis as the main technique, we tested 2 AD hypotheses in this model: (1) the glucose hypometabolism as an alternative AD hypothesis and (2) the cholinergic deficit as an important characteristic of AD pathology. Hippocampus was chosen because cholinergic function in this region is severely affected in AD. In comparison, the striatum was chosen because it contains cholinergic interneurons and is less affected in AD.
Methods: In this study, we used male Wistar rats of 190-220 g body weight (5 weeks of age). The rats were injected intracerebrally with STZ at a dose of 3 mg/kg (2x1.5 mg/kg; „high dose“) and 0.6 mg/kg („low dose“) with saline as control. After 21 days, samples were collected to investigate cholinergic and metabolic changes using histology, biochemistry, and neurochemistry. Brain injury was confirmed using GFAP staining and Fluoro jade staining in the hippocampus. Mitochondrial toxicity was investigated by measurement of mitochondrial
respiratory function in both hippocampus and striatum. Cholinergic markers such as acetylcholinesterase (AChE) activity, choline acetyltransferase (ChAT) activity, and choline transporter (CHT-1) activity, commonly known as high-affinity choline uptake (HACU), were measured in both hippocampus and striatum using a spectrophotometer and a scintillator.
Microdialysis is the main technique in our study. It was done in awake animals under behavioral or pharmacological stimulation. We used a self-built probe with a semi-permeable membrane (pore size of 30 kDa) that was implanted in either hippocampus or striatum. The probes were then perfused with artificial cerebrospinal fluid (aCSF) supplemented with 0.1 μM neostigmine for extracellular acetylcholine level measurement. During the perfusion, small hydrophilic compounds from brain extracellular space diffuse into the dialysates. Dialysates of 15 minutes intervals were collected for 90 minutes and used for analysis. After collection of dialysates for the first 90 minutes (basal data), rats were moved to an open field box (35x32x20 cm) for behavioral stimulation. After collection of the second 90 minute dialysates, the rats were transferred back to the microdialysis cage and dialysates were collected for another 90 minutes. On day 2, after collection of dialysates under basal conditions, 1 μM scopolamine was added to the perfusion solution for stimulation of acetylcholine release. The dialysates were also collected for 90 min followed by another 90 min of dialysis without scopolamine. The microdialysate samples were then analyzed as follows. ACh level was measured by HPLC-ECD. Glucose metabolites (glucose, lactate, pyruvate) were measured by a CMA-600 microanalyzer. An alternative energy metabolite (beta-hydroxybutyrate/BHB) was measured by GC-MS. Choline and glycerol as membrane breakdown markers were also measured by HPLC-ECD and CMA-600 microanalyzer, respectively. Markers of oxidative stress (isoprostanes) were measured using a commercially available ELISA kit.
...
Currently, due to the misuse of antibiotics, we are facing a major public health problem. The resistance to antibiotics of certain bacterial strains makes the treatment of infections very complex.
In this context, the present thesis project concerns the study of a bacterial efflux complex capable of transporting antibiotics from the cytoplasm to the outside of the cell. This complex is composed of an inner-membrane Major Facilitator Superfamily (MFS) transporter (EmrB, E. coli multidrug resistance), a channel of the outer membrane TolC (Tolerance to Colicin E1) and a periplasmic adapter (EmrA, E. coli multidrug resistance). Unlike RND-type efflux systems (such as AcrAB-TolC), little is known about the MFS-type EmrAB-TolC system. It is therefore important to study the entire complex on a structural and functional level, to analyse the marked differences between these two types of transport systems. The goal of my thesis project was to study at least one EmrAB-TolC complex from a structural point of view. For my studies the aim was to isolate the complex directly from bacteria overexpressing the three protein partners. In a first step, 15 homologous EmrAB-TolC systems were identified and their corresponding genes amplified from genomic DNA of different Gram-negative bacteria. Among the genes of the 15 systems, the genes coding for the E. coli and V. cholerae systems were further studied. The expression vectors encoded fluorescent markers for the monitoring of the expression levels of different proteins and for studying the formation of complexes. In a first step, the different protein expression levels (EmrB-mRFP1 and EmrA-sfGFP) were studied for several expression strains of E. coli by measuring the red and green fluorescence levels and by Western blot (anti-His, Myc, and Strep for EmrB, EmrA, and TolC). The E. coli strain C41(DE3) was best suited for co-expression of EmrAB-TolC. In a second step, the FSEC (Fluorescence detection Size Exclusion Chromatography) methodology was used to identify a complex suitable for structural study. Thus this method enabled the observation that the EmrAB-TolC complex of E. coli was produced in higher amount than that of V. cholerae. The final co-purification protocol consists in perfoming a gentle lysis of the bacteria using lysozyme, then after solubilization with DDM, the purification is started by a Ni2+-NTA affinity chromatography step followed by a size exclusion chromatography step. Finally, the fractions containing the three protein partners are used for the detergent-exchange by amphipol A8-35 before the structural study by electron microscopy. Negative stain EM-micrographs displayed elongated objects with a length of 33 nm in side view. An average image of EmrAB-TolC shows similarities to that of the AcrAB-TolC complex observed under similar conditions. Similarities included the characteristic densities of TolC. Whereas differences were found in the lower part of EmrAB which is thinner than the lower part of AcrAB. The densities visible above the amphipol-ring correspond to EmrA, which displays a channel-like structure as in AcrA. The channel however seems to extend further towards the amphipol belt. Since EmrB does not have an extended periplasmic domain as the RND proteins have, these densities are therefore solely assigned to EmrA. EmrA, on the other side, contacts TolC akin to the interaction of AcrA/MexA to their cognate outer membrane channels (TolC/OprM) in a ‘tip-to-tip’ fashion.
This thesis investigates the acquisition pace and the typical developmental path in eL2 acquisition of selected phenomena of German morphosyntax and semantics and compared them to monolingual acquisition. In addition, the influence of ‘Age of Onset’ and of external factors on eL2 acquisition is examined.
To date, the most studies on eL2 acquisition focused on language production. Based on mostly longitudinal spontaneous speech data of only small number of children, they indicate that eL2 learners acquire sentence structure and subject-verb-agreement faster than monolingual children, whereas the acquisition of case marking causes them more difficulties. Moreover, similar developmental paths to those of monolingual children are claimed. Only several studies examined comprehension abilities in eL2 learners, however overwhelmingly in cross-sectional design. The findings from comprehension studies on telic and atelic verbs, and on wh-questions indicate that eL2 children acquire their target-like interpretation faster than monolingual children. The same acquisition stages towards target-like interpretation like in monolingual acquisition are assumed as well. Taking together, to date, no study exists, that examines comprehension and production abilities in a large group of eL2 learners of German in a longitudinal design.
This thesis extends the previous results by investigating pace of acquisition, impact of factors, and individual developmental paths in a longitudinal design with large groups of participants. Language data of 29 eL2 learners of German (age at T1: 3;7 years, LoE: 10 months) and 45 monolingual German-speaking children (age at T1: 3;7) are examined. The eL2 learners were tested in six test rounds (age at T6: 6;9 years). The monolingual children were tested in five test rounds (are at T5: 5;7). The standardized test LiSe-DaZ (Schulz & Tracy, 2011) was employed to examine children’s language skills.
eL2 learners show a significantly greater rate of change, thus faster acquisition pace, than monolingual children in the following scales: comprehension of telicity, comprehension of wh-questions, production of prepositions, and production of conjunctions. These phenomena are acquired early in monolingual children. No differences regarding acquisition pace between eL2 children and monolingual children are found for comprehension of negation, production of case marking, and production of focus particles. These phenomena are acquired late in monolingual development and involve semantic and pragmatic knowledge. The findings of faster acquisition pace of several phenomena are in line with several studies that reported that eL2 children develop faster than monolingual children.
Independent on whether a phenomenon is acquired early or late, no effects of external factors on eL2 children’s performance are found. These findings indicate that acquisition of core, rule-based phenomena is not sensitive to external factors if the first exposure to L2 takes place around the age of three.
Moreover, eL2 children show the same developmental stages and error types in comprehension of telicity, comprehension of negation, production of matrix and subordinate clauses. This is also independent on how fast they acquire a structure under consideration. Thus, these findings provide a further support for similar developmental paths of eL2 and monolingual children towards target-like comprehension and production.
The genus Giraffa likely evolved around seven million years ago in Indo-Asia and spread over the Arabian-African land bridge into Eastern Africa. The oldest fossil of the African lineage was found in Kenya and dated to 7-5.4 Mya. Beside modern giraffe, four additional African species have likely existed (G. gracilis, G. pygmaea, G. stillei, and G. jumae). Based on their morphological similarities, G. gracilis is often considered to be the closest relative of the modern giraffe. Nevertheless, the phylogeny within the genus Giraffa is largely unresolved.
Modern giraffe (Giraffa sp.) have been neglected by the scientific community for a long time and still very little is known about their biology. Traditionally, present-day giraffe have been considered a single species (G. camelopardalis) which is divided into six to eleven subspecies, with nine subspecies being the most accepted classification. This classification was based on morphological differences and geographic ranges. However, recent genetic analyses found hidden diversity within Giraffa and proposed four genetically distinct giraffe species (G. camelopardalis, G. reticulata, G. tippelskirchi, G. giraffa) with presumably little gene flow among them.
Gene flow on a population level is the exchange of genetic information among populations facilitated by the migration of individuals between populations. Additionally, it is an important criterion to delineate species, because many species concepts, especially the Biological Species Concept, rely on the concept of reproductive isolation. Yet, new genetic methods are identifying an increasing number of species that show signs of introgressive hybridization or gene flow among them. Therefore, strict reproductive isolation cannot always be applied to delineate species, especially in young, probably still diverging, species such as giraffe.
Therefore, giraffe are ideal study organisms to investigate the level of gene flow in recently diverged species with adjacent or potentially overlapping ranges. Furthermore, their recent classification as “Vulnerable” by the IUCN and their unreliable distribution maps require the genetic evaluation of their population structure, distribution and conservation status.
In Publication 1 (Winter et al. (2018a), Ecological Genetics and Genomics, 7–8, 1–5), I studied the distribution and matrilineal population structure of Angolan giraffe (G. giraffa angolensis) using sequences from the cytochrome b gene (1,140 bp) and the mitochondrial control region for individuals from across their known range and beyond, and additionally including individuals from all known giraffe species and subspecies. The reconstruction of a phylogenetic tree and a mitochondrial haplotype network allowed to identify the most easterly known natural population of Angolan giraffe, a population that was previously assigned to their sister-subspecies South African giraffe (G. giraffa giraffa), indicating the limit of classification by morphology and geography. Furthermore, the analyses show that Namibia’s iconic desert-dwelling giraffe population is genetically distinct, even from the nearest population at Etosha National Park, suggesting very limited, if any, natural exchange of matrilines. Yet, no geographic barriers are known for this region that would prevent genetic exchange. Therefore, the two populations are likely on different evolutionary trajectories. Limited individuals with an Etosha haplotype further suggest that translocation of Etosha giraffe into the desert population had only a minor impact on the local population. Two separate haplogroups within Etosha National Park suggest an “out of Etosha” radiation of Angolan giraffe to the East followed by a later back-migration.
In Publication 2 (Winter et al. (2018b), Ecology and Evolution, 8(20), 10156–10165), I investigated the genetic population structure of giraffe across their range (n = 137) with focus on the amount of gene flow among the proposed giraffe species with a 3-fold increased set of nuclear introns (n = 21). Limited gene flow of less than one effective migrant per generation, even between the closely related northern (G. camelopardalis) and reticulated giraffe (G. reticulata) further supports the existence of four giraffe species by a different methodology, gene flow. This is significant because most species concepts build on reproductive isolation. Furthermore, this result is corroborated by four distinct major clades in a phylogenetic tree analysis, and distinct clusters in Principal Component Analysis and STRUCTURE analysis. All these analyses suggest a low level of genetic exchange among the four giraffe species and, therefore, a high degree of reproductive isolation in accordance with the Biological Species Concept (BSC). In Addition, only a single individual in 137 was identified as being potential of natural hybrid origin, which promotes the four-species concept further. ...
The compound class of the fabclavines was described as secondary or specialized metabolites (SM) for Xenorhabdus budapestensis and X. szentirmaii. Their corresponding structure was elucidated by NMR and further derivatives could be identified in both strains. Biochemically, fabclavines are hybrid SMs derived from two non-ribosomal-peptide-synthetases (NRPS), one type I polyketide-synthase (PKS) and polyunsaturated fatty acid (PUFA) synthases. In detail, a hexapeptide is connected via partially reduced polyketide units to an unsual polyamine. Structurally, they are related to the (pre-)zeamines, described for Serratia plymuthica and Dickeya zeae. Fabclavines exhibit a broad-spectrum bioactivity against a variety of different organisms like Grampositive and Gram-negative bacteria, fungi, protozoa but also against eukaryotic celllines.
In this work, the fabclavine biosynthesis was elucidated and assigned to two independently working assembly lines. The NRPS-PKS-pathway is initiated by the first NRPS FclI via generation of a tetrapeptide, which is elongated by the second NRPS FclJ, leading to a hexapeptide. Alternatively, FclJ can also act as direct start of the biosynthesis, resulting in the final formation of shortened fabclavine derivatives with a diinstead of a hexapeptide. In both cases, the peptide moiety is transferred to the iterative type I PKS FclK, leading to an elongation with partially reduced polyketide units. The resulting NRPS-PKS-intermediate is still enzyme-bound. The PUFA-homologues FclC, FclD and FclE in combination with FclF, FclG and FclH belong to the polyamine-forming pathway. Briefly, repeating decarboxylative Claisen thioester condensation reactions of acyl-coenzym A building blocks lead to the generation of an acyl chain in a PKS- or fatty acid biosynthesis-like manner. The corresponding β-keto-groups are either completely reduced or transaminated in a specific and repetitive way, resulting in the concatenation of so-called amine-units. The final β-keto-group is reduced to a hydroxy-group and the intermediate is reductively released by the thioester reductase FclG. A subsequent transamination step leads to the final polyamine. The NRPS-PKS- as well as the polyamine-pathway are connected by FclL. This condensation domain-like protein catalyzes the condensation of the polyamine with the NRPS-PKS-part, which results in the release of the final fabclavine. The results are described in detail in the first publication (first author).
Fabclavine biosynthesis gene cluster (BGC) are widely spread among the genus Xenorhabdus and Photorhabdus. In Xenorhabdus strains a high degree of conservation regarding the BGC synteny as well as the identity of single proteins can be observed. However, Photorhabdus strains harbor only the PUFA-homologues. While in Photorhabdus no product could be detected, our analysis revealed that the Xenorhabdus strains produce a large chemical diversity of different derivatives. Briefly, the general backbone of the fabclavines is conserved and only four chemical moieties are variable: The second and last amino acids of the NRPS-part, the number of incorporated polyketide units as well as the number of amine units in the polyamine. In combination with the elucidated biosynthesis, these variables could be assigned to single biosynthesis components as diversity mechanisms. Together with the 10 already described derivatives, a total of 32 derivatives could be detected. Interestingly, except for taxonomic closely related strains, all analyzed strains produce their own set of derivatives. Finally, we could confirm that the fabclavines are the major bioactive compound class in the analyzed strains under laboratory conditions. The results are described in detail in the second publication (first author).
Together with our collaboration partner Prof. Selcuk Hazir a potent bioactivity against Enterococcus faecalis, which is associated with endodontic infections, could be contributed to X. cabanillasii. Here, we could confirm that this bioactivity can be assigned to the fabclavines. The results are described in detail in the third publication(co-author).
Among the genus Xenorhabdus, X. bovienii represents an exception as its NRPS and PKS genes of the fabclavine BGC are missing or truncated, resulting in the exclusive production of polyamines. Furthermore, its PUFA-homologue FclC harbors an additional dehydratase (DH) domain. Upon extensive analysis a yet unknown deoxy-polyamine was identified and assigned to this additional domain. Finally, the DH domain was transferred into other polyamine pathways. Regardless of an in cis or in trans integration, the chimeric pathways produced deoxy-derivatives of its naturally occurring polyamines, suggesting that this represents another diversification mechanism. The results are described in detail in the attached manuscript (first author).
In optogenetischen Anwendungen, welche die Manipulation von zellulären Aktivitäten durch Licht ermöglichen, werden die Eigenschaften von mikrobiellen Rhodopsinen, einer Familie natürlich vorkommender lichtgesteuerter Proteine, ausgenutzt.
In der vorliegenden Arbeit wurden die einwärts transportierende Protonenpumpe NsXeR, sowie die auswärts Natriumionenpumpe KR2 untersucht. Des Weiteren wurden Tandem Proteine betrachtet, die mikrobielle Rhodopsine kombinieren mit dem Chemokinrezeptor CXCR4, der durch SDF1 aktiviert und anschließend in Endosomen internalisiert wird.
Für die Untersuchung des Mechanismus, der die Vektorialität in NsXeR bestimmt, wurde eine umfassende elektrophysiologische Studie durchgeführt. In Patch Clamp Messungen an NsXeR exprimierenden NG108-15 Zellen wurden bei kontinuierlicher 561 nm Beleuchtung aktive Einwärtsströme entgegen eines elektrochemischen Gradienten gemessen. Ein Einfluss des intrazellulären pHs auf die steady-state Ströme und deren Abfallkinetik konnte nicht festgestellt werden. Der Vergleich der exponentiellen Abfallrate k2 mit den Übergängen im NsXeR Photozyklus, lässt den Schluss zu, dass der ratenlimitierende Schritt der MII Zerfall ist.
Die elektrogenen Schritte im NsXeR Photozyklus wurden mit elektrischen Messungen an der black lipid membrane (BLM) an NsXeR Proteoliposomen bestimmt. Die Belichtung mit 20 ns Lichtpulsen bei 556 nm rufen Spannungssignale hervor, die exponentiell gefittet wurden, wobei drei elektrogene Schritte identifiziert werden konnten. Bei pH 7.4 betrugen die ermittelten Zeitkonstanten etwa 220 µs, 1 ms und 15 ms, denen 42%, 10% und 48% an der Gesamtladungsverschiebung zugeordnet wurden. Die elektrogenen Schritte konnten den Übergängen im Photozyklus zugeordnet werden, wobei der erste Schritt mit t1 dem MI Aufbau (Deprotonierung Schiff’sche Base, Protonenabgabe zur intrazellulären Seite) zugeschrieben wurde. t2 wurde dem MI→MII Übergang (Switch, Zugänglichkeitsänderung vom Intra- zum Extrazellulären) zugeordnet und t3 korreliert mit dem MII Zerfall (Reprotonierung Schiff’sche Base, Protonenaufnahme von der extrazellulären Seite).
Die Kinetik und der Ladungstransportanteil des zweiten elektrogenen Schritts haben keine starke pH Abhängigkeit, was sich dadurch erklären lässt, dass t2 durch eine Konformationsänderung bestimmt wird. t1 und t3 werden bei höheren pH Werten beschleunigt, was sich bei t1 mit einer erleichterten intrazellulären Protonenabgabe erklären lässt. Für t3 wurde eine Reprotonierung durch eine Donor Gruppe Asp76 vorgeschlagen. Die pH-sensitive Änderung der relativen Ladungstransferanteile des ersten und dritten elektrogenen Schrittes (∆ΨI und ∆ΨIII) wurden durch eine mögliche Verzögerung der frühen Protonenabgabe bei niedrigen pH Werten erklärt.
Der mutmaßliche Protonenakzeptor Asp220 wurde gegen Asn und Glu ausgetauscht und in Patch Clamp sowie UV-Vis Spektroskopie Messungen untersucht. Für D220N wurden keine Pumpströme und kein Einfluss auf die maximale Absorptionswellenlänge λmax festgestellt. D220E dagegen führte zu einer Erniedrigung des pKa-Werts der Schiff’schen Base und zu einer Verminderung der Iss-Abfallsrate k2 in Patch Clamp Dauerbelichtungsmessungen (D220E k2 = 27.1 ± 1.8 Hz, Wildtyp k2 = 83.1 ± 2.6 Hz). Daraus konnte geschlossen werden, dass Asp220 wesentlich für den Protonentransport ist und nicht als Gegenion für die protonierte Schiff’sche Base dient.
In Patch Clamp Experimenten bei 561 nm Dauerbelichtung und zusätzlicher gepulster Belichtung bei 355 nm wurde der Blaulichteffekt an NsXeR untersucht, bei dem Proteine im M Intermediat ein Photon absorbieren und unter Reprotonierung der Schiff’schen Base in den Grundzustand zurückkehren.
Für NsXeR konnte eine Potentialabhängigkeit für die Richtung der transienten Ströme, die durch die
355 nm Belichtung hervorgerufen wurden, festgestellt werden. Beim NsXeR Blaulichteffekt scheint eine
Reprotonierung der Schiff’schen Base von beiden Seiten möglich zu sein, was auf die unterschiedlichen Zugänglichkeiten in den beiden M Zuständen MI und MII zurückgeführt wurde. Es wurde ein Modell vorgeschlagen, welches auf einem potentialabhängigen Gleichgewicht zwischen MI und MII basiert.
In Patch Clamp Messungen an KR2 exprimierenden NG108-15 Zellen wurden die Pumpströme untersucht, die durch den auswärts Transport von Na+ und H+ hervorgerufen wurden. Die Na+-Konzentrationen der intra- und extrazellulären Lösungen wurden symmetrisch variiert und die steady-state Ströme Iss bei 532 nm Dauerbelichtung betrachtet. Mit steigender Na+-Konzentration zeigte sich ein Übergang von einer linearen Potentialabhängigkeit der Iss, zu einem sättigungsähnlichen Verhalten bis hin zu einer fast glockenförmigen Form. Da die exponentielle Abfallrate der steady-state Ströme k2 in ihrer Potentialabhängigkeit mit den Iss korrelierte, konnte geschlossen werden, dass die Ströme überwiegend kinetisch limitiert sind. Die Erhöhung der Rate k2 mit steigender Na+-Konzentration zwischen -120 mV und -60 mV deutet darauf hin, dass die Na+-Aufnahme von der intrazellulären Seite bei diesen Bedingungen die Limitierung für die Pumpe darstellt.
Unter Na+-“freien” Bedingungen wurde der Einfluss des intrazellulären pHs untersucht. Für die Rate k2 wurde eine Erhöhung bei niedrigen pH Werten festgestellt und die Potentiale E0 (Iss = 0 pA) verschoben bei niedrigem intrazellulärem pH zu hyperpolarisierenden Potentialen. Daraus lässt sich schließen, dass die steady-state Ströme durch den Transport von Protonen hervorgerufen wurden.
In Messungen mit gepulster 530 nm Belichtung wurden die transienten Pumpströme gemessen und durch exponentielles Fitten des Stromabfalls drei elektrogene Schritte identifiziert. Eine Abhängigkeit vom Potential und der Na+-Konzentration konnte nur für den dritten Schritt mit der Rate 1/τ3 festgestellt werden, wobei 1/τ3 mit der Na+-Konzentration und bei positiveren Potentialen steigt. Unter Na+-“freien” Bedingungen steigt 1/τ3 auch mit niedrigeren intrazellulären pH Werten. Die elektrogenen Schritte wurden dem KR2 Photozyklus zugeordnet, wobei ein Modell angewendet wurde, das einen M1→M2 Übergang einführt. Diesem wurde der zweite elektrogene Schritt zugeordnet. Die relativen Ladungstransportanteile Q2 und Q3 des zweiten und dritten elektrogenen Schrittes sind sowohl potential- als auch Na+-abhängig. Um dieses Verhalten zu erklären, wurde ein Modell vorgeschlagen, bei dem ein Ausgleichsladungstransfer in Form von einer Protonenabgabe und -wiederaufnahme während des Photozyklus eingeführt wurde.
In Patch Clamp Messungen wurde die erhaltene Funktionalität der ChR2 Mutante ChR2(L132C) mit erhöhter Ca2+-Permeabilität im Tandem Protein tCXCR4/CatCh nachgewiesen. Auch die Internalisierung von tCXCR4/CatCh konnte anhand der zeitabhängigen Abnahme des CatCh-Signals nach der CXCR4-Aktivierung durch SDF1 in Strommessungen beobachtet werden. Für tCXCR4/Arch, ein Tandem Protein mit einer Protonenpumpe, wurde die SDF1-induzierte Internalisierung mit Hilfe der konfokalen Laser-Scanning-Mikroskopie betrachtet und eine Kolokalisierung der Fluoreszenz des im Tandem exprimierten YFP und der eines gelabelten CXCR4-spezifischen Antikörpers in intrazellulären Vesikeln beobachtet. Bei Behandlung mit dem CXCR4 Antagonisten AMD3100 wurde die Kolokalisierung hauptsächlich in der Zellmembran festgestellt, da die Internalisierung blockiert war. Die Tandem Protein könnten als in intrazellulären Organellen wirkende optogenetische Werkzeuge eingesetzt werden für z.B. die Manipulation der intrazellulären Ca2+-Konzentration.
Synaptic plasticity is the activity dependent alteration of the composition, form and strength of synapses and believed to be the underlying mechanism of learning and memory formation. While initial changes in synaptic transmission are caused by second messenger signaling pathways and rapid modifications in the cytoskeleton, to achieve stable and persistent changes at individual synapses, the expression of new mRNAs and proteins is required. The central dogma postulated that the cell body is the only source of newly synthesized proteins. For neurons, with their unique morphology, this meant that proteins would need be transported long distances, often hundreds of microns, to reach their destined locations in dendrites and at spines. To overcome this limitation, neurons have developed a strategy to regulate protein synthesis locally by distributing thousands of mRNAs into neuronal processes and use them for local protein synthesis. Ample research has demonstrated the importance of local protein synthesis to many forms of long-term synaptic plasticity. One potential regulator of mRNA localization and local translation in neurons are non-coding RNAs. Intensive work over the past decades has highlighted the importance of non-coding RNAs in many aspects of brain function. The aim of this thesis is to obtain a better understanding of the role of non-coding RNAs in synaptic function and plasticity in the murine hippocampus. For this, we focused our studies on two classes of non-coding RNAs.
In the first part of my thesis, I describe our efforts on characterizing circular RNAs, a novel and peculiar family of non-coding RNAs, in the murine hippocampus by combining high throughput RNA-Sequencing with fluorescence in situ hybridization. Furthermore, we investigated the mechanisms of circular RNA biogenesis in hippocampal neurons by temporarily inhibiting spliceosome activity and analyzing the differentially regulated circular RNAs.
Cancer is the major cause of death besides cardiovascular disease. Leukaemia represents the most prevalent malignancy in children with a frequency of 30 % and is one of the ten leading types of cancer in adults. Philadelphia Chromosome-positive B-ALL (Ph+ B-ALL) is driven by the cytogenetic aberration of the reciprocal chromosomal translocation t(9;22)(q34;q11) leading to the formation of the Philadelphia chromosome with a BCR-ABL1 fusion gene. This fusion gene encodes a BCR-ABL1 oncoprotein which is characterized by a constitutively enhanced tyrosine kinase activity promoting amplified proliferation, differentiation arrest and resistance to cell death. Ph+ B-ALL is considered the most aggressive ALL subtype with a long-term survival rate in the range of only 30 % despite intensive standard of care including chemotherapy in combination with a tyrosine kinase inhibitor (TKI) followed by allogeneic stem cell transplantation after remission for clinically fit patients.
The efficacy of chemotherapy has long been mainly attributed to tumour cell toxicity while immune modulating effects have been overlooked, especially in light of known immunosuppressive properties. Accumulative evidence, however, emphasizes the ability of chemotherapeutic agents, including TKIs, to normalise or re-educate a dysfunctional tumour microenvironment (TME) resulting in enhanced anti-tumour immunity. One of the underlying mechanisms of immune modulation is the induction of immunogenic cell death (ICD). ICD is an anti-tumour agent-induced cell death modality determined by the capacity to convert cancer cells into anti-cancer vaccines. The induction of ICD relies on the release of damage-associated molecular patterns (DAMPs) from dying tumour cells succumbing to ICD. Translocation of CALR to the cell surface, extracellular secretion of ATP and release of HMGB1 from the nucleus are key hallmarks of ICD that mediate anti-tumour immunity upon binding to antigen presenting cells resulting in a tumour antigen-specific immune response. Besides these molecular determinants, ICD is functionally defined by the inhibition of tumour growth in a vaccination assay in which mice are injected with tumour cells exposed to the potential ICD inducer in-vitro and then re-challenged with live tumour cells of the same cancer type. Both molecular and functional criteria determine the gold standard approach to assess ICD. By increasing the immunogenicity of cancer cells, ICD contributes to the restoration of immunosurveillance as an essential feature of tumour rejection, which is clinically reflected by improved therapeutic efficacy and disease outcome in patients. Therefore, identifying novel ICD inducers is an objective of interest in the context of cancer therapy.
In respect of these considerations, the aim addressed in the present work is the examination of the second-generation TKI Nilotinib for the ability to induce ICD. The thesis is set in the context of the group's research on the role of Gas6/TAM signalling within the TME regarding the pathogenesis of acute leukaemia. In in-vivo experiments of our research group it has been consistently observed that the use of Nilotinib enhances the anti-leukaemic immunity mediated by a deletion of Gas6. Against the background of increasing importance of chemotherapeutic agents as potent modulators of a dysregulated TME, it was hypothesized that Nilotinib may synergize with a Gas6-deficient environment by inducing ICD in Ph+ B-ALL cells.
In growth inhibition and Annexin V/Propidium iodide cell death assays Nilotinib was shown to induce cell death in concentration-dependent manner that occurs bimodally in terms of cell death modality ranging between apoptosis and necrosis. By ICD marker analysis, comprising flow-cytometric detection of CALR exposure, chemoluminescence-based ATP measurement and immunoblotting for HMGB1, it was found that Nilotinib-induced cell death is not accompanied by CALR exposure and ATP secretion, but is associated with the release of HMGB1. In macrophages co-culture experiments with Nilotinib-treated leukaemic cells, no relevant shift in terms of macrophages activation and polarisation was observed in either a juxtacrine or paracrine setup. In consistency with the results obtained in the in-vitro experiments, Nilotinib was not potent to elicit a protective immune response in mice within a vaccination assay.
Conclusively, Nilotinib was identified to not qualify as bona fide ICD inducer. The role of Nilotinib-induced cell death and HMGB1 release are proposed as objective for further investigation concerning the synergistic interplay between Nilotinib and a Gas6-deficient environment. Efforts addressing exploration and optimisation of the immunological potential of chemotherapeutic agents are a promising approach aimed at providing cancer patients with the best possible treatment in future.
Xenorhabdus and Photorhabdus are bacterial genera that live in symbiosis with entomopathogenic nematodes of the genera Steinernema and Heterorhabditis, respectively. These nematodes infect insect larvae through the trachea and then enter the hemocoel. Once inside the hemocoel, the nematodes release the bacteria through their intestine. Thereafter, the bacteria become active and kill the larvae within 48 h. During this process, the immune system of the insect host is compromised by molecules produced and secreted by the bacteria. This illustrates that the bacteria possess not only a large arsenal of biological weaponry such as antibiotics and fungicides but also lipases, proteases, etc. Therefore, they are not only able to kill the insect but also protect the cadaver from other food competitors.
During the past decades, a large number of natural products have been identified from Xenorhabdus and Photorhabdus. However, the targets and functions for many of these biological molecules are still unknown. Therefore, the goal of the doctoral thesis is to elucidate the modes of action of these natural products from Xenorhabdus and Photorhabdus with the main focus on non-ribosomal peptides (NRPs). The work can be divided into two parts. Initially, it starts with the synthesis of natural compounds and various chemically modified derivatives. Besides that, a number of peptides were synthesized for other projects to either verify their structures or quantify the amount produced by the bacteria. Then, secondary analysis methods are applied and provide additional insight into the modes of action of these compounds.
During the thesis, I carried out peptide synthesis either manually or with an automatic synthesizer system from Biotage. Here, the Fmoc-protecting group strategy was preferred in most cases. Natural products, such as silathride, xenoautoxin, phenylethylamide, tryptamide, rhabdopeptide, 3-hydroxyoctanoic acid, and PAX, were produced during this process. Furthermore, new peptide derivatives derived from synthetic NRPS approaches using the XU concept or SYNZIP were generated as standards.
Most of these natural compounds were experimentally verified by MIC tests (broth microdilution, plate diffusion) to be biologically active. For example, silathride, phenylethylamide, and tryptamide showed quorum quenching effects when tested against Chromobacterium violaceum. Initial results from collaborators (PD Dr. Nadja Hellmann/Mainz) showed that tryptamide and phenylethylamide interact with membrane or membrane proteins.
(R)-3-hydroxyoctanoic acid was synthesized to verify the molecule structure of phototemtide A, a cyclic lipopeptide with antiprotozoal activity. The rhabdopeptides are another class, which showed remarkable antiprotozoal effects. However, their mode of action was unknown. These compounds are relatively short peptide sequences, which contain hydrophobic residues, such as valine, leucine, or phenylalanine. Moreover, they possess N methylation, resulting in a rod-shaped highly hydrophobic structure. In this work, I synthesized eight new derivatives of rhabdopeptides for photo-affinity labeling (PAL). These molecules should react covalently under UV-light irradiation with the biological target of the peptides. In addition, these derivatives can be enriched in a pull-down assay using click chemistry. Afterward, analytic methods such as mass detection (proteome analysis) can be applied to elucidate the protein targets.
The PAX peptides derivatives are well-known to have anti-microbial activities and believed to be secreted into the environment by the producing bacteria. However, I found that the majority of these peptides are located in the cell pellet fraction and not in the supernatant. This has been shown through quantification using HPLC MS. New PAX derivatives were synthesized, which carry a moiety suitable for covalent modification using click-chemistry, therefore being functionalizable with a fluorescence dye. In collaboration with Dr. Christoph Spahn (Prof. Dr. Mike Heilemann group), we used confocal, as well as super-resolution microscopy, in particular, single-molecule localization microscopy (SMLM) to investigate the spatial distribution of clickable PAX molecules and revealed that they localize at the bacterial membrane. Furthermore, bioactivity assays revealed that the promotor exchanged X. doucetiae PAX mutants, which do not produce PAX molecules without chemical induction (hereby termed as pax-), were more susceptible to several insect AMPs tested. Based on these findings, a new dual mechanism of action for PAX was proposed. Besides the previously shown antimicrobial activity, these molecules with a positive net charge of +5 (pH = 7) would bind to the negatively charged bacterial surface. Hereby, the surface charge (typically negative) would be inversed resulting in a protective effect for Xenorhabdus against other positively charged AMPs. Furthermore, PAX was investigated as AMP against E. coli to study its antimicrobial mechanism of action. Here, the results show that PAX can disrupt the E. coli membrane at higher concentrations (> 30 µg/ml), enter the cytosol, and lead to reorganization of subcellular structures, such as the nucleoid during this process.
Another aspect of secondary analysis is the application of proteomic analysis. Therefore, I induced X. nematophila, X. szentirmaii, and P. luminescens with insect lysate. These samples were analyzed using HPLC-MS/MS (Q Exactive) together with a database approach (Maxquant/Andromeda). The results showed that in all strains the lipid degradation and the glyoxylate pathway were induced. This is in line with the given insect lysate diet, which mostly contained lipids. Moreover, several interesting unknown peptides and proteins were also upregulated and might get into the focus of future research.
Background: Previous studies have demonstrated that CF (Cystic Fibrosis) prognosis is dependent of three major parameters: FEV1 (Forced Expiratory Pressure in one second), BMI (Body Mass Index) and need of intravenous antibiotic therapy. The CF centres of Frankfurt, Germany, and Moscow, Russia, care for cystic fibrosis patients. We decided to investigate and compare both centers from 1990 to 2015. No comparable study has been published so far.
Method: German patient data was collected from the national cystic fibrosis database “Muko.web”. Missing values were extracted from the Hospital Information System. Russian patient data were taken directly from the medical records in Moscow. In a descriptive statistical analysis with Bias and R Studio the values were compared.
Result: A total of 428 patients from Moscow (217 male, 211 female; 348 (81,3%) were P. aeruginosa positive) and 159 patients from Frankfurt (92 male, 67 female; 137 (86,2%) with P. aeruginosa positive) were compared with regard to P. aeruginosa positivity, BMI, FEV1 and need of intravenous antibiotic therapy. CF patients in Moscow stratified by age groups had lower BMI than CF patients in Frankfurt (age 16-18: p=0,003; age 19-22: p=0,004; age 23-29: p<0,001; age 30-35: p<0,001; age 36-66: p=0,024). In a matching pairs analysis including 100 patients from Frankfurt and 100 patients from Moscow for the year 2015 FEV1 was significantly lower in Moscow patients (p<0,001).
Conclusion: BMI, FEV1 and need of intravenous therapy have significant impact on survival and on quality of life of CF patients. A lower BMI and a lower FEV1 result in a worse survival and determine the prognosis. This study showed a significant difference in prognostic parameters between Frankfurt and Moscow in the crosssectional analysis for the year 2015. A further study should evaluate this difference to show whether this difference will be found over a longer period of time.
Development of treatment strategies of chronic inflammatory disorders relies on on-going progress in drug discovery approaches and related molecular biologics. This study presents a gene reporter-based approach of phenotypic screening for anti-inflammatory compounds in the context of rheumatoid arthritis (RA).
CEBPD gene, used as the target gene for the screening readout, encodes CCAAT/enhancer binding protein delta (C/EBPδ) transcription factor (TF). Structural and regulatory characteristics of CEBPD gene as well as function of C/EBPδ TF in the context of inflammation satisfied assay requirements. C/EBPδ TF acts as a key regula-tor of inflammatory gene transcription in macrophages (Mϕ) and is observed to con-tribute to disease development in both a rodent model of RA and RA patient biopsies.
Despite well-described pro-inflammatory effects of C/EBPδ TF, it functions as a cell context-specific signal integrator showing also an anti-inflammatory activity. Conse-quently, both activation and inhibition of CEBPD alike may display a desired anti-inflammatory effect. The aim of this study was to develop a high-throughput screening assay for
CEBPD-modulating compounds and confirm hit compounds’ anti-inflammatory effects via gene expression analysis.
Generation and characterization of a multi-gene-reporter cassette 1.0 encoding enzy-matic secreted alkaline phosphatase (SEAP) gene reporter was a priority during the assay development. Chemiluminescent SEAP assay demonstrating high assay sensitivi-ty, broad linear range, high reproducibility and repeatability was chosen to monitor activity of the defined CEBPD promoter (CEBPD::SEAP). PMA-differentiated and M1-polarized THP-1-derived Mϕ stably expressing multi-gene-reporter cassette 1.0 were used as the assay’s cellular system. mRNA expression of both reporter CEBPD::SEAP and endogenous CEBPD mirrored each other in response to a LPS and IFN-g-triggered inflammatory stimulus (M1 treatment), even though the defined CEBPD promoter re-gion, utilized in the assay, contained only the most proximal and known regulatory se-quences. SEAP chemiluminescence in the reporter cells´ supernatant reliably correlat-ed with the M1 treatment-induced CEBPD::SEAP gene expression. The final screening protocol was developed for semi-automatic screening in the 384-well format.
In total, 2054 compounds from LOPAC®1280 and ENZO®774 libraries were screened twice
using the enzymatic SEAP readout with subsequent analysis of 18 selected compounds: nine with the highest and nine with the lowest signals, further characterized by qPCR. Gene expression levels of endogenous CEBPD, CEBPD::SEAP reporter as well as, IL-6,
IL-1β, and CCL2 as inflammatory markers were quantified. qPCR assays failed to corre-late to SEAP readout in 15 compounds within three standard deviations (SDs) from sol-vent control: nine low signal and six high signal compounds. Demonstrating both assay sensitivity and specificity, a correlation between qPCR gene expression and SEAP readout was observed for three hit compounds with signals above three SDs: BET inhib-itors (BETi) GSK 1210151A and Ro 11-1464 as well as an HDAC inhibitor (HDACi) vori-nostat. The control compound trichostatin A (TSA) that reproducibly upregulated SEAP readout is also an HDAC inhibitor with a similar structure to vorinostat and was there-fore included in the anti-inflammatory phenotype analysis.
The observed suppression of IL-6, IL-1ß, and CCL2 gene expression by hit compounds suggested their anti-inflammatory effect in THP-1 reporter Mϕ. mRNA expression of
IL-6 and CCL2 was suppressed by HDACi and BETi at both 4 and 24 hours, while BETi reduced IL-1β mRNA expression 24 hour time point. BETi significantly upregulated gene expression of both reporter CEBPD::SEAP and endogenous CEBPD, 4 hours after M1 treatment. At the same time point, HDACi completely abolished the mRNA expres-sion of the endogenous CEBPD, while simultaneously upregulating mRNA expression of the reporter CEBPD::SEAP. The use of the most proximal 300 base pairs region of en-dogenous CEBPD promoter, making the upstream regulatory elements unavailable in the assay, may account for differential expression levels of SEAP and C/EBPδ TF. This observation corroborated the need to include a longer and more extensive CEBPD´s gene regulatory area. Thus, an improved multi-gene-reporter cassette 2.0 was gener-ated to be used on the basis of a bacterial artificial chromosome (BAC) covering CE-BPD´s genomic area of about 200,000 base pairs.
The generated screening assay is flexible, reliable, and sensitive displaying potential for drug discovery and drug repurposing. The pharmacological modulation of CEBPD gene expression, first reported for GSK 1210151A, Ro 11-1464, and vorinostat, contrib-utes to the understanding of inflammatory responses in Mϕ and may have RA thera-peutic applications.
The post-transcriptional modification of the canonical nucleoside uridine into its rotational isomer pseudouridine occurs in non-coding as well as coding RNA and is the most abundant post-transcriptional modification in all kingdoms of life. While the occurrence of pseudouridine has been linked to the enhancement of stability and the codon-anticodon interaction in tRNAs, enhancement of the translation efficiency in rRNAs, regulatory functions in spliceosomal snRNA and nonsense codon suppression in mRNA, its exact role in many RNAs is still ambiguous. The uridine to pseudouridine isomerization can either be catalyzed by one of various standalone pseudouridylases or it can be performed in an RNA-guided manner by H/ACA ribonucleoproteins. In eukaryotes, the guide RNA always adapts a conserved bipartite, double-hairpin conformation. Each hairpin contains an internal RNA-loop motif, which can recruit a specific substrate RNA via base pairing. The catalytically active RNP is formed by the interactions of the guide RNA with four proteins. While Cbf5 forms the catalytically active center, Nop10 and Nhp2 perform auxiliary functions and Gar1 is involved in substrate turnover. Up until now, most structural knowledge about H/ACA RNPs has been derived from archaeal complexes, while the exact structure-function-relationships between RNA and proteins in eukaryotic RNPs is still ambiguous. While archaeal H/ACA RNPs share many similarities with eukaryotic RNPs and act as good model system, there are also many differences between them like eukaryotic specific protein domains as well as the overall bipartite complex structure, dictated by the snoRNA. Investigating pseudouridylation by eukaryotic H/ACA RNPs opens up a broad area of research and helps to gain a better understanding of this enzyme class – especially since malfunction of H/ACA RNPs has been linked to the genetic disease Dyskeratosis congenita as well as several types of cancer.
The main goal of this thesis was to gain new insights into the RNA/protein interactions in the eukaryotic snR81 H/ACA snoRNP from Saccharomyces cerevisiae on a structural as well as dynamical level. In the first part of this thesis, the main goal was to in vitro prepare a functionally active snR81 H/ACA RNP. The guiding snoRNA was prepared by in vitro transcription and purification, while the Saccharomyces cerevisiae proteins were recombinantly expressed from Escherichia coli. Apart from the full length, bipartite snR81 snoRNP, several sub-complexes of the RNP were reconstituted. Therefore, snoRNA constructs were designed and prepared, which only contained a single hairpin motif of the complex. Furthermore, snoRNA constructs in which the apical hairpin stem was replaced by a stable tetraloop were prepared, to investigate the influence of the apical stem on protein binding and activity. Also, for the eukaryotic proteins, a shortened version of Gar1 (Gar1Δ) was utilized, which lacks the eukaryotic specific RGG domains, that have been characterized as accessory RNA binding motifs. Reconstituted snoRNPs were utilized in catalytic activity assays, monitoring the turnover rate of uridine to pseudouridine. For this purpose, radioactively labeled substrate RNAs were prepared by phosphorylation and splinted ligation of oligonucleotides and were objected to reconstituted H/ACA RNPs under single as well as multiple turnover conditions. In the second part of this thesis, the RNA/protein interactions were dissected via single molecule FRET spectroscopy. Therefore, the snoRNA was labeled with an acceptor fluorophore via NHS ester/amine-reaction. Furthermore, the snoRNA contained a biotin-handle, allowing immobilization of the complex during the experimental time-window of the spectroscopic analysis. Eukaryotic specific protein Nhp2 was labeled with a donor fluorophore via “click” chemistry, which included the chemical synthesis and incorporation by genetic code expansion of non-canonical amino acids. The interactions of Nhp2 with the different snoRNA constructs (standalone-hairpins “H5” and “H3”, as well as hairpins lacking the apical binding motif “H5Δ” and “H3Δ”) were monitored on a single molecule level.
In summary, it was possible to gain new insights into the complex structure and the dynamical behavior of the still sparsely characterized eukaryotic H/ACA RNPs. Especially, new knowledge could be obtained about the hairpin specific behavior on the bipartite RNA complex structure, including the rather ambiguous role of the protein Nhp2 and the contribution of the eukaryotic specific features of Gar1 in their interaction with the guide/substrate RNA.