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Impact of proteostasis and the ubiquitin proteasome system on myeloid cell function in the CNS
(2023)
Cellular protein homeostasis (proteostasis) maintains a functional proteome and thus proper cell function. Proteostasis is facilitated by the ubiquitin-proteasome system (UPS), an intracellular protein turnover machinery ensuring clearance of damaged, misfolded, old and/or unneeded regulatory proteins. This is particularly important in the central nervous system (CNS), where it is linked to neurodegeneration. Disruptions of the proteostasis systems cause the accumulation of misfolded proteins which are commonly seen in progressive neurodegenerative diseases also linked to neuroinflammation. Proper UPS function can protect cells from the accumulation of defective proteins, neurodegeneration and neuroinflammation. Furthermore, it has been found that loss of function mutations in the genes encoding UPS components are linked to systemic inflammation including neuroinflammation and/or neurodevelopmental disorders. Proteasome defects in patients suffering from these disorders cause decreased proteasome activity, accumulation of proteins, activation of proteotoxic stress responses and systemic inflammation. However, the molecular link between proteotoxic stress and the initiation of inflammatory signalling remained unclear. In Article 2, we summarized the importance of the UPS in immune cell proteostasis and function including activation of innate and adaptive immune responses. Although UPS function is notably important in innate immune signalling, the current understanding of the role of UPS in myeloid cell function in the CNS is limited. We also indicated the involvement of impaired UPS function in sterile systemic inflammation including neuroinflammation as well as tumour diseases and pathogen manipulation of immune cells.
To investigate the molecular link behind proteasome impairment and systemic inflammation in the brain, we focused on microglia cells as the only immune residents of the CNS. In Article 1, we used a pharmacological inhibitor called bortezomib which targets β5 and β5i/LMP7 subunit activities in standard proteasome (SP) and immunoproteasome (IP), respectively. We showed for the first time on the molecular level that inhibition of proteasome activity by bortezomib triggers the accumulation of ubiquitylated proteins, proteotoxic stress responses and innate immune signalling activation depending on the induced proteotoxic stress response called unfolded protein response (UPR) in murine microglia. In particular, activation of the inositol-requiring protein 1α arm of UPR upon bortezomib treatment leads to systemic inflammation as indicated by type I interferon (IFN) response.
IP enhance the proteolytic capacity of UPS by rapid clearance of proteins upon immune signalling activation. Microglia, like other immune cells, exhibit constitutive expression of IP as well as SP to maintain their cellular proteostasis. In Manuscript 3, we studied the particular impact of IP impairment on microglial cellular function. We showed accumulation of ubiquitin-modified proteins and activation of proteotoxic stress responses in IP-impaired mouse and human microglia models. Moreover, we identified possible IP substrates in microglia using β5i/LMP7 knockout mice as an IP deficiency model and, examined how IP deficiency affects microglia function. IP deficient microglia affected the ubiquitylation levels of proteins involved in multiple pathways such as immune responses, energy metabolism, cytoskeleton organisation, cell cycle and ribosome function. Based on the molecular analysis, we confirmed sterile activation of innate immune signalling mechanisms in IP impaired microglia. This is driven by the proteotoxic stress sensor protein kinase R (PKR). In addition, we were able to show that IP impairment altered levels of the microglial activation markers, which are also involved in motility, adhesion and phagocytosis of microglia.
In this thesis, we highlight that UPS function is necessary to maintain microglial proteostasis and, that impairment of proteasome activities triggers sterile inflammation in microglia via activation of proteotoxic stress responses. The described activation of innate immune signalling mechanisms in microglia upon proteasome impairment may be considered as new therapeutic targets for patients suffering from rare protesomapathies or other disorders linked to dysregulated immune signalling.
Protamine (PRT) is a positively charged protein, which is widely used in medicine as an adjunct to certain preparations of insulin and as a rapidly-acting antidote for heparin, particularly to neutralize the effects of high heparin concentrations needed for anticoagulation during cardiac surgical procedures using cardiopulmonary bypass. It has been demonstrated that PRT and heparin form multimolecular complexes and that these complexes have high immunogenicity in a mouse model. Studies in this thesis provide new insights into the pathophysiology of anti-PRT/heparin antibodies. The results of study I showed that the administration of PRT combined with heparin is responsible for high immunoglobulin G (IgG) immunization after cardiac surgery. A subset of these antibodies was able to induce platelet activation in a way similar to that observed by heparin-induced thrombocytopenia (HIT). Using an animal model, we demonstrated that anti-PRT/heparin antibodies are capable of platelet destruction in the presence of PRT and heparin. Moreover, our data suggests that platelet-activating anti-PRT/heparin antibodies at surgery are potentially associated with postoperative thrombocytopenia and an increased risk for thromboembolic events. In study II, the immune response against PRT/heparin complexes was investigated. This study showed a relatively fast development of IgG with no general preceding IgM formation. In addition, patients undergoing liver transplantation developed anti-PRT/heparin antibodies without previous exposure to PRT. These results suggest that a previous contact with the antigen(s) itself or other antigens with molecular mimicry induced this immune response. In fact, we were able to identify Neutral Protamine Hagedorn (NPH) insulin and core histones (DNA-binding proteins) as potentially antigenic candidates for a previous immunization. Furthermore, the findings of study III demonstrate the ability of anti-PRT/heparin antibodies to activate platelets in the presence of NPH insulin in a heparin-dependent way suggesting that diabetic patients may have an enhanced risk for thromboembolic complications if treated with NPH insulin and possibly while receiving prophylactic heparin. These observations justify further clinical investigations to assess the impact of the interaction between anti-PRT/heparin antibodies and PRT-mimicking antigens, such as NPH insulin or histones.
Oils and fats from natural origin are sustainable sources for a broad range of economically relevant products in food, feed, fuel, oleochemical, and cosmetic industries. Thereby, a huge variety of lipids or lipid-derived products exist which distinguish themselves by their unique physical properties making them suitable for their individual applications. To obtain such functional lipids in an environmentally friendly manner, enzymes can be employed. In that context, lipases have been proven to be valuable biocatalysts in lipid modification, which are broadly applied in industry. Even though they have been implemented successfully in the dairy, baking, and detergent industries, there is an increasing demand for the expansion of their utilization. New technologies like protein engineering and the implementation of process development are employed in solving this task. Within the enzymes in lipid modification, lipases are the most applied catalysts and in this thesis their utilization was expanded successfully to the implementation of novel separation processes and the production of improved drug delivery matrices.
Microalgae are aquatic, unicellular, eukaryotic organisms, which perform photosynthesis. They have gained interest within the last decades not only for biofuel production due to their high amount of lipids, but also for pharmaceutical and for nutraceutical purposes. Interesting compounds are proteins, carbohydrates, or pigments, such as carotenoids. However, microalgae possess strong and rigid cell walls, which hinder a sufficient and yet, gentle extraction of those valuable compounds. Although standard extraction techniques are available, several shortcomings occur, e.g. high energy demand, use of environmentally harmful solvents or alteration of compounds due to heat or chemicals. Therefore, an alternative method is needed, which is able to address these disadvantages. Physical plasmas were thus studied to answer the question whether they are able to disintegrate the cell walls of microalgae effectively and yet, without degradation of the extractives.
First step of the thesis was to find a suitable plasma source that has an effect on the cell walls because plasma effects, such as electric fields, shockwaves, UV light emission, and the generation of reactive species can be tailored with the respective setup. It was found that spark discharges are most effective for the extraction of Chlorella vulgaris, which was chosen as model organism. All extraction yields were compared to reference methods, whereat microwave radiation was found to be the most effective reference method and were hence, applied for comparative studies.
For the next step, proteins were selected as targets to answer the question, which differences can be determined between plasms-treated and microwave-radiated proteins are observable although the extraction yields were equal. Furthermore, plasma effects, especially the effects of reactive species on the extracted proteins had to be studied. Findings indicate that heat sensitive proteins, such as photosystem-related proteins, or histones are better extractable with spark discharges than with microwave exposure and the effect of reactive species is only minor.
The last step was to determine, which plasma effect is responsible for the observed cell wall disintegration. Therefore, the tensile strength of Chlorella vulgaris was determined and compared to the shockwave pressure, which is generated from the spark channel. It was proven that the shockwave pressure exceeds by far the tensile strength of the microalgae an can be thus held responsible for mechanism for cell wall rupture.
In this thesis, it was found that spark discharges are a promising alternative for the extraction of valuable compounds from microalgae. The discharges are not only effective, but also gentle enough for sensitive compounds, such as proteins or pigments.
Plus‐strand RNA [(+)RNA] viruses are the largest group of viruses, medically highly relevant human pathogens, and are a socio‐economic burden. The current global pandemic of the severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) shows how a virus has been rapidly spreading around the globe and that– without an antiviral treatment– virus trans mission is solely dependent on human behavior. However, other (+)RNA viruses such as rhino‐, noro‐, dengue‐ (DENV), Zika, and hepatitis C virus (HCV) are constantly spreading and expanding geographically. As in the case of hepatitis C, since its first identification in the 1970s, it took more than 30 years to understand the HCV structure, genome organiza t ion, life cycle, and virus‐host interplay leading to the cure of a chronic and life‐threatening disease. However, no vaccination or antiviral treatment exists for most (+)RNA viruses. Con sequently, a precise and comprehensive analysis of the viruses, their life cycles, and parasitic interactions with their hosts remains an important field of research. In the presented thesis, we use mathematical modeling to study the life cycles of (+)RNA viruses. We analyze replication strategies of closely related (+)RNA viruses, namely HCV, DENV, and coxsackievirus B3 (CVB3), to compare their life cycles in the presence and ab sence of the host’s immune response and antiviral drug treatment and consider different viral spreading mechanisms. Host dependency factors shape the viral life cycle, contribut ing to permissiveness and replication efficiency. Our mathematical models predicted that host dependency factors, such as ribosomes, and thus the virus’ ability to hijack the host cell’s translation machinery play an essential role in the viral genome replication efficiency. Furthermore, our mathematical model suggested that the availability of ribosomes in the vi ral life cycle is a crucial factor in disease outcome: the development of an acute or chronic disease. Even though the host developed strategies to attack the virus, e.g., by degrading the viral genome, blocking the viral protein production, and preventing viral spread, viruses found strategies to countermeasure those so‐called host restriction factors derived from the immune system. Our mathematical models predicted that DENV might be highly effective in blocking the cell’s attempts to recognize the invader. Moreover, we found ongoing HCV RNAreplication even with highly effective antiviral drugs that block processes in the viral life cycle. Furthermore, we found alternative pathways of infection spread, e.g., by HCV RNA carrying exosomes, which may be a possible explanation for reported plasma HCV RNA at the end of treatment, found in a subset of patients. Hence, the mathematical models presented in this thesis provide valuable tools to study the viral replication mechanism in detail. Even though being a simplification of reality, our model predictions confirm and explain known and suggest novel biological mechanisms. In the pre sented thesis, I will summarize and discuss key findings and contextualize model predictions in the broader scientific literature to improve our understanding of the viral dynamics and the virus‐host interplay.
This thesis deals with thickness optimization of shells. The overall task is to find an optimal thickness distribution in order to minimize the deformation of a loaded shell with prescribed volume. In addition, lower and upper bounds for the thickness are given. The shell is made of elastic, isotropic, homogeneous material. The deformation is modeled using equations from Linear Elasticity. Here, a basic shell model based on the Reissner-Mindlin assumption is used. Both the stationary and the dynamic case are considered. The continuity and the Gâteaux-differentiability of the control-to-state operator is investigated. These results are applied to the reduced objective with help of adjoint theory. In addition, techniques from shape optimization are compared to the optimal control approach. In the following, the theoretical results are applied to cylindrical shells and an efficient numerical implementation is presented. Finally, numerical results are shown and analyzed for different examples.
This thesis draws a comprehensive picture about the radiation and diversification of truncatelloidean gastropods across the south pacific. It covers three more specifc studies focussing on the Truncelloideans from Fiji, Vanuatu and New Caledonia, respectively. And a conclusive analysis that combines the results of the three more specific studies and enhances them using species from the Austral Islands, Lord Howe Island, the Indonesian island Sulawesi as well as several species from New Zealand and Australia. Molecular phylogenies were calculated using four nuclear gene fragments (ITS2; 18S rRNA; 28S rRNA and Histone 3) besides the mitochondrial COI and 16S rRNA. Further molecuular data was used to calculate dated phylogenies, perform ancestral range reconstructions and develop a modified molecular barcoding approach.
Adaptation mechanisms within the B cell composition for successful human and murine pregnancies.
(2021)
Introduction
A well-balanced immune maternal status is essential for favourable outcome of pregnancy. Due to their complexities, not all immune adaptations that promote tolerance during pregnancy are known. To understand the adaptation of the B cell compartment, we analysed and compared B cell lymphopoiesis in different lymphoid tissues in a number of murine models.
Furthermore, we focused on the humoral immune response during pregnancy. We analysed immunoglobulin profiles in human subjects and mice during pregnancy.
These cellular alterations are subject to the influence of chemokines, among others. Therefore, we assessed serum levels of B cell activation factor to clarify its effects during pregnancy.
Methods
For analysis of the human peripheral B cell compartment, peripheral blood samples from age-matched non-pregnant and pregnant women without pregnancy complications, immunological disease or acute/chronic inflammation were collected and sub-classified into four different groups: non-pregnant, and first, second, or third trimester of pregnancy. The experiments, based on a mouse model, were performed with 8-week-old female mice: clinically healthy non-pregnant (CBA/J (H2k)), pregnant mice with normal gestation (BALB/c (H2d) x CBA/J (H2k)), and mice with pregnancy loss (DBA/2J (H2d) x CBA/J (H2k)). Subsequently, peripheral blood mononuclear cells from blood and lymphatic organs were isolated following standard protocols. The B cell analysis was performed by flow cytometry. The immunoglobulin serum levels of the human and murine subgroups were quantitated using Bio-Plex isotyping assay and analysed by a Bio-Plex reader. To quantify B cell activating factor (BAFF) in serum of pregnant and non-pregnant mice a BAFF enzyme-linked immunosorbent assay was used. The concentrations were determined by using a FLUOstar OPTIMA microplate reader. All statistical analyses were performed using the Kruskal–Wallis test with Dunn’s post-test in GraphPad Prism software. P values of < 0.05 were considered statistically significant.
Results
We were able to demonstrate B cell lymphopenia in mice bone marrow downstream of pre-pro B cells, irrespective of pregnancy outcome. The mature bone marrow B cells did not show this adjustment mechanism during normal gestation.
Closer inspection of the splenic tissue revealed expansion and activation of marginal zone B cells in mice with a normal pregnancy. However, this was not observed in mice suffering from pregnancy disturbances. Natural antibodies secreted from marginal zone B cells were also present at higher concentrations in serum of pregnant mice, compared to non-pregnant animals.
We also found significantly higher levels of natural antibodies in serum of pregnant women compared to non-pregnant age-matched controls. Analysis showed significantly lower levels of BAFF in mice with normal pregnancy as compared to non-pregnant mice.
Conclusions
We are able to show mechanisms within the B cell compartment as well as the change within the natural antibodies that might be crucial for successful pregnancy in both humans and mice. Furthermore, BAFF seems to play a central role as a mediator of peripheral B cell compartment and B cell lymphopoiesis in the bone marrow for successful pregnancy.
Bats (Chiroptera) form the second largest order of mammals and with over 1,250 species, they represent about 20% of all mammalian species worldwide. They are the only mammals with true and sustained flight and distributed all over the world except the arctic regions. Moreover, bats entered specific ecological niches and with their food spectra, they reduce different arthropod populations as well as disperse seeds and pollen of plant species in various regions and habitats.
Bats also have a crucial role in spreading high-pathogenic and zoonotic viruses, harbor in general more viruses (zoonotic and non-zoonotic), and, related to the species, number even more than rodents. However, clinical symptoms of viral diseases are rarely reported in bat communities. Also seroconversions after infection were not reported for a variety of viruses found in bats. Since the incidence of virus-positive bats estimated in passive surveillance studies is usually very low, it is a question how such viruses can use bats as reservoir hosts. There is obviously a special evolutionary relationship between the pathogens and bats as hosts, which are based on possibly physiologic adaptations also in resistance and immunity.
In this thesis, the two lyssaviruses, European Bat Lyssavirus 1 and 2 (EBLV-1 and -2) were chosen as a model to investigate the immune response of European bats against viral infection in vitro. Lyssaviruses are the causative agents of rabies, a fatal zoonotic disease with neurotropic characteristics.
One main question to investigate was in which way bats act as reservoir host and developed a high disease resistance. The present thesis is based on three hypotheses about innate immune response against lyssavirus infection:
A) In bats specific peripheral resistance mechanisms evolved which reduce the risk of systemic viral infection after a hypothesized airborne transmission and infection via nasal epithelium supported by the social structure of and communication within bat communities.
B) The co-evolution of EBLV and the innate resistance of bats resulted in a very effective type I interferon response to inhibit a systemic lyssavirus infection.
C) The specific physiology of body temperature of bats with daily torpor depresses the viral replication but favours the type I interferon response.
To analyze the interferon-based resistance mechanisms, the type I interferon (IFN) genes of two European bats species (Eptesicus serotinus and Myotis myotis) were cloned and sequenced. Using established cell lines from the respiratory nasal epithelium (MmNep), olfactory nasal epithelium (MmNol), and Bulbus olfactorius brain (MmBr), the type I IFN response along a possible airborne infection route was investigated. The anti-viral effects and induction of IFNs/interferon stimulated genes (ISGs) in each cell line were also investigated in detail after infection in vitro. Finally, the influence of different temperatures on lyssavirus replication was analyzed in cell culture experiments.
The results indicated that (a) along the hypothesized airborne infection route the susceptibility for lyssavirus infections is decreased, (b) the type I IFN activity in contrast is increased contributing to a limitation of lyssavirus replication and (c) an obvious influences of varying cultivation temperatures on the resistance against lyssavirus infections, which favor the IFN response and repressing lyssavirus replication.
The result from these in vitro studies supports the hypothesis of a special co-evolution between lyssaviruses and bats. However, in vivo studies on the relevance in infected animals are missing so far. This model could also explain the generally limited pathogenicity of bat-associated viruses.
Recent climate change has affected the forest system comprehensively. Northern hemisphere elevational treelines are considered as a key environment for monitoring the effects of current anthropogenic climate change. Moreover, trees from these areas are also widely employed in paleo-climate reconstructions. The stability of the tree growth climate relationship under current scenario is crucial for all tree ring based climate researches. It is important to investigate how trees respond to this rapid environmental change at altitudinal treelines. Tree cores from 21 treeline sites of three species (Pinus tabulaeformis, Picea crassifolia, and Sabina przewalskii) from Northeastern Tibetan have been conducted in this thesis. The instable correlations between tree growth and climate are the general response pattern of trees from all study sites in NE Tibetan Plateau. Picea crassifolia shows the most instable response to climate factors (mean monthly temperature and total monthly precipitation). Pinus tabulaeformis and Sabina przewalskii just showed instable and divergent responses to their main limiting climate factors but no clear trend was found which is limited by the few sample sites. Corresponding to divergent responses of Picea crassifolia to mean monthly temperature, most radial growth of Picea crassifolia were inhibited by this climate change type drought, only few trees within same sites grew faster due to temperature increasing during recent decades. The divergence response mainly started in last 30 years in six of eleven sample sites over the Northeastern Tibetan Plateau. North-westerly drier sites showed a large percentage of trees per site with a negative correlation to temperature and mostly southerly moister sites showed more mixed responses with both negatively and positively responding trees within site. Concurrent with the regional pattern, low elevation sites show mostly negative correlations with temperature and high elevation sites show more mixed responses. As the hydrothermal conditions of the investigation area changed to a drier and warmer combination, drought stress on tree growth have been intensifying over time and expanding spatially from the middle to most of our study area during the last half century. The Picea crassifolia tree growth climate relationship conducted on an elevational gradient with four different levels from upper treeline to lower treeline at the NE Tibetan Plateau. Results show that upper treeline trees show divergent growth trends and divergent responses in recent decades. Trees from lower treeline show a strengthening drought stress signal over time and no divergent growth trends within sites. This potential ecological reaction of tree populations to changing environmental conditions shows an implications for using trees to reconstruct climate, since the indiscriminate use of tree ring data from sites showing opposite responses to increasing warming could cause mis-calibration of tree ring based climate reconstructions, and over- or underestimation of carbon sequestration potential in biogeochemical models. The physiological response of Sabina przewalskii tree growth to major limiting climate factors based on the Vaganov-Shashkin (VS) model indicated that precipitation during the early growing season, especially in May and June, has significant effect on tree growth, while temperature mainly affects tree growth by warming-induced drought and by extending the growing season in the NE Tibetan Plateau. Under current and projected climate scenarios, modeling results predict an increase in radial growth of Sabina przewalskii around the Qaidam Basin, with the potential outcome that regional forests will increase their capacity to sequester carbon. However, most Picea crassifolia trees growing at lower elevations than Sabina przewalskii might be continue stressed by the warming induced drought and might decrease radial growth in future.
All types of muscles use Ca2+ as their main intracellular messenger. In skeletal muscle fibers abnormal levels of intracellular calcium result in altered contractile properties, altered energy metabolism, and altered gene expression. Moreover, long term failure of normal Ca2+ homeostasis can lead to cell death of muscle fibers by necrosis and apoptosis. Elevations of intracellular Ca2+ levels are more and more regarded as the reason for pathological changes and muscle fiber damage in Duchenne Muscular Dystrophy (DMD). DMD is a severe recessive x-linked muscle disease caused by mutations in the dystrophin gene. The characteristics of DMD are muscle tissue wasting and fibrosis. Both muscle wasting and intracellular Ca2+ are to be reflected in changes of muscle force. Several Ca2+ conducting channels including transient receptor potential (TRP) channels are supposed to account for the abnormal Ca2+ homeostasis in DMD. Gene expressions of TRP channels have been studied in human and mouse skeletal muscle and among others TRPC3, TRPC6 and TRPV4 channels were found to occur in skeletal muscles. The present study followed the hypothesis that TRPC3, TRPC6 and TRPV4 are functional in skeletal muscle fibers and that they contribute to muscular Ca2+ homeostasis. Further, it was assumed that dysfunction of the mentioned TRP channels contributes to abnormal contractile properties and pathology and of dystrophin-deficient muscle. To study Ca2+ changes in mouse skeletal muscle fibers the fluorescent calcium indicator Fura-2 was used. Further, the technique of Mn2+ quench of Fura-2 fluorescence was applied. Muscle force measurements of mouse soleus and diaphragm strips were performed. To elucidate abnormalities of TRP channel function in dystrophin-deficient muscle, muscles and muscle fibers of mdx mice were studied. Hyperforin, an activator of TRPC6 channels elicited increases of calcium levels in wildtype muscle fibers. These increases were partly inhibited by the TRPC6 inhibitor 1-(5-chloronaphthalenesulfonyl) homopiperazine hydrochloride (ML-9). The TRPC3/TPRC6 activator 1-oleoyl-2-acetyl-sn-glycerol (OAG) resulted in increased calcium entry, which was attenuated by ML-9. 2-aminoethoxydiphenylborane (2-APB), an unspecific TRP channel inhibitor, suppressed calcium entry in muscle fibers under basal conditions. In addition, the specific TRPC3 inhibitor Pyr3, strongly inhibited background calcium entry. The TRPV4 activator 4α-phorbol 12,13-didecanoate (4α-PDD) induced significant increased calcium entry and this increase could be inhibited by the TRPV4 inhibitor HC 067047. During muscle force recordings ML-9 significantly inhibited twitches and tetani and accelerated muscle fatigue during sustained repetitive stimulation. The results indicate that TRPC3, TRPC6 and TRPV4 are functionally expressed in mouse muscle fibers. TRPC3 stays active under the basal conditions and contributes to background calcium entry. In contrast, TRPC6 and TRPV4 did not seem to be active at resting conditions, but could be pharmacologically activated. TRPC6 may play a role to counteract the calcium loss under long-term muscle fatigue. Though TRPC3 and C6 play a role for muscular Ca2+ homeostasis, it is unclear whether and how the two channels associate and cross-talk with each other in skeletal muscle cells. In mdx fibers Pyr3 inhibited background calcium influx stronger that in WT fibers, implying a possible over-activation of TRPC3 channels in mdx muscle fibers. At later stages mdx muscle showed marked decrease in force reflecting muscle wasting. Soleus showed moderate decrease and diaphragm showed severe decrease (more than 60%) in force. Resistance to muscle fatigue was shown in mdx soleus muscle when compared with WT soleus muscle. Diaphragm segments of mdx mice showed very strong resistance to muscle fatigue. The results indicate a substantial loss of muscle mass, an increase in oxidative fiber types and a reduction of fast fatigable muscle fibers. It is concluded that the hypothesis of functional expression of TRPC3, TRPC6 and TRPV4 in mouse skeletal muscle has been confirmed. The results give improved knowledge about the relation of Ca2+ homeostasis, mdx pathology and TRP channels. Diaphragms of old mdx mice show severe muscle weakness but the remaining fibers of the diaphragm showed strong fatigue-resistance. The application of a TRPC3 inhibitor may be a promising treatment to prevent high Ca2+ mediated muscle damage in muscular dystrophy.
Liu–II coal pit is a typical example of China’s deep coal mines which is seriously threatened by groundwater inrush from the underlying carboniferous Taiyuan limestone formation. An exhaustive data set of this confined aquifer exists. The aquifer lies 45 m∼ 60 m below the major coal seam. A traditional artesian aquifer test has been performed in order to assess the hydraulic properties, e.g. transmissivity (T) and storage coefficient (S). This artesian aquifer test is conducted with four simultaneously operating production wells while the discharge of each production well varied with time. The results of this test suggest that the aquifer is heterogeneous. Therefore, the according problems are: (1) how to analyze the artesian aquifer test with linearly declining discharge; (2) how to deal with multiple production wells in an aquifer test; (3) how to adequately consider aquifer heterogeneity. Thus, the objective of this thesis is to solve these problems. 1) As opposed to classical above-ground pumping tests, it is difficult to control the discharge rate of the production well in a deep mine artesian aquifer test since the hydraulic pressure is extraordinary high. Moreover the discharge rate won’t descend rapidly to zero, thus the analytical solution of Jacob and Lohman (1952) type curve for the artesian aquifer test will not be applicable. It is more reasonable to analyze the test as a pumping test with variable discharge. It is considered to rebuild a hydrogeological conceptual model which is similar with Theis (1935) model but with the variable discharge. A general equation for any discharge variability is given. Its application for the linearly declining discharge is presented subsequently, and a type curve of this equation with linearly declining discharge is given as well. After that, a simple numerical model is built by FEFLOW to simulate an artificial pumping test with the linearly declining discharge by assigning different parameter sets for transmissivity and storage coefficient. The type curve method is applied to evaluate transmissivity and storage coefficient for the linearly declining discharge well. The deviation between the given values of transmissivity and storage coefficient in FEFLOW and the values of those calculated by matching point are sufficiently small. Thus, when the discharge of production well declines linearly, a type curve method as an empirical method is reasonable and gives satisfactory values of these hydrogeological parameters. 2) In some cases, it is necessary to conduct a pumping test (or an artesian aquifer test) with several pumping wells (or production wells) which work simultaneously in order to discharge maximum quantity of groundwater. Normally, the superposition method or numerical simulation is applied to analyze the test result. However, a new approach called “Well Generalization Method” is defined and analyzed in this thesis. It is an easy–to–use approach for hydrogeologist to estimate the aquifer parameters while conducting an aquifer test. Since the key point of this approach is using a generalization well to substitute the pumping (or production) wells, it is obvious that this approach will generate the estimated error of parameters. Accordingly, several scenarios are analyzed and discussed based on the artificial type aquifer designed in FEFLOW. A homogeneous aquifer and a heterogeneous aquifer which is generated by geostatistical stochastic simulation technique (see 3)) are discussed separately. As a result, this approach is feasible and applicable under some conditions when the calculated observation well is arranged more than about 2.5 times the scale of the multi–pumping–wells field away from the center of the multi–pumping–wells field, furthermore, the maximum deviation of drawdown resulting from these observation wells will be less than 0.5 m, and the estimated value of transmissivity will be 0.44% smaller than real value. 3) Finally aquifer heterogeneity is addressed, in order to check the introduced method for applicability under realistic conditions. It has been described that aquifer heterogeneity plays a major role in hydrodynamic processes (e.g. de Marsily et al., 1998). Geostatistics which is considered as a useful tool for characterizing the spatial variability of transmissivity is applied to solve this problem. Based on the results of the artesian aquifer test conducted in Liu–II coal pit, a model of spatial variability of transmissivity is developed. Sequentially, the variogram model is applied in ordinary kriging to interpolate the transmissivity distribution, and in sequential Gaussian simulation to simulate a random field of transmissivity data in order to reflect its small scale variability. A comparison of the results of estimation and simulation of transmissivity indicates that the simulated values better reflect the spatial variability, reversely, the estimated values are much smoother.
Bats belong to the most gregarious and diverse mammals with highly complex social behaviors. Despite extensive research on their ecology and social behavior in some bat species, gained insights are restricted to only few of the more than 1300 species. In the recent past, bats have also become a central topic of a different branch of research: Since the 1990s bats came to the fore of virologists and immunologists due to the bats’ apparent importance as reservoir hosts and vectors of several (mostly tropical) diseases. While this research is focused mainly on emerging infectious diseases linked to bats, and their zoonotic potential, little has been invested regarding the link between disease transmission and bat social systems.
In my work, I aim at filling this gap by merging automated daily roosting observations, social network analysis, and a virological screening in Natterer’s bats (Myotis nattereri). In a collaborative approach, my co-workers and I analyzed the social structure of individually marked Natterer’s bats, their astrovirus detection rate and transmission pathways within their colony, as well as roosting interactions between different co-occurring con- and heterospecific bat colonies.
We discovered Natterer’s bats to display a very divergent social network structure that contradicts the findings of previous studies on large fission-fusion groups. Contrary to the modular social network structure found in e.g. primates or other bats species, the social network of Natterer’s bats consists of only one highly interconnected community. Moreover, although the close proximity between bat hosts in the colony should strongly promote direct transmission, we found indications that astrovirus infections follow at least partly an indirect transmission pathway via contaminated roost use. Lastly, our results prove that co-occurring con- and heterospecific bat colonies, e.g. as in this study Natterer’s bats, brown long-eared bats and Bechstein’s bats, can influence each other in their roost use by avoiding conspecific roosts and by being attracted towards those of heterospecifics. This holds implication for the transmission of parasites and pathogens within and between different colonies with opportunities for spillovers. To conclude, this multidisciplinary study led to valuable insights in the hitherto hidden mechanisms within and among bat colonies.
In this thesis we have revisited the formation of the excitonic insulator (EI), which realizes an exciton condensate. In contrast to optically created exciton condensates, the EI forms in thermal equilibrium and is solely driven by the Coulomb attraction between electrons and holes. The EI phase is anticipated to occur near the semimetal-semiconductor (SM-SC) transition at low temperatures. Depending from which side the EI is approached, it forms due to a BCS-type condensation of electron-hole pairs or a Bose-Einstein condensation (BEC) of excitons. The extended Falicov-Kimball model (EFKM) is the minimal model the EI can be described with. This model describes spinless fermions in two dispersive bands (f band and c band), that interact via a local Coulomb repulsion. The EFKM is also used to describe electronic ferroelectricity (EFE). Both phases, the EI and EFE-type ordering, are characterized by a spontaneous f-c hybridization in the EFKM. We have presented the EI phase, the EFE phase, and the orderings they compete with. Moreover, we have determined the ground-state phase diagram of the EFKM. We have focused particularly on the anticipated BCS-BEC crossover within the EI and have analyzed the formation scenarios. The exciton spectrum and the exciton density in the normal phase close to the critical temperature give information about relevant particles and therefore the nature of the transition. We have demonstrated that the whole EI is surrounded by a halo", that is, a phase composed of electrons, holes and excitons. However, on the SM side, only excitons with a finite momentum exist. These excitons appear only in a small number and barely influence the SM-EI transition. This phase transition is driven by critical electron-hole fluctuations, generated by electrons and holes at the Fermi surface. On the SC side, excitons with arbitrary momenta exist. Most notably, we have found the number of zero-momentum excitons to diverge at the SC-EI transition, signaling the BEC of these particles. Within the EI phase, there is a smooth crossover from the BCS regime to the BEC regime. One of the promising candidates to observe the EI experimentally, is the transition-metal dichalcogenide 1T-TiSe2. Strong evidences were found favoring an EI scenario of the charge-density-wave (CDW) formation in this material. However, some aspects point to a lattice instability to drive the CDW transition. We have addressed this issue by analyzing the recently discovered chiral property of the CDW in 1T-TiSe2. We have found that the EI scenario is insufficient to explain a stable, long range chiral charge ordering. Lattice degrees of freedom must be taken into account. In particular, nonlinear electron-phonon coupling and phonon-phonon interaction are crucial. By estimating appropriate model parameters for 1T-TiSe2, we have suggested a combination of excitonic and lattice instability to drive the CDW transition in this material. Experiments in 1T-TiSe2 and other materials suggest that the coupling to the lattice is non-negligible. We have extended therefore the model by an explicit exciton-phonon interaction, and have analyzed crucial effects of this interaction. While the single-particle spectrum is not modified qualitatively, the electron-hole pair spectrum changes significantly. The inclusion of the phonons lead to a massive collective mode in the ordered ground state in contrast to the case for vanishing exciton-phonon coupling, where the mode is acoustic. We have suggested that a gapless collective mode leads to off-diagonal long range order. This questions that the ground state for finite exciton-phonon coupling represents a condensate.
For many years, rangeland ecologists have debated about whether the state of semi-arid and arid rangelands is the expression of an ecological equilibrium or non-equilibrium dynamics reached in response to grazing livestock. Since the problem has been considered at different spatial scales, it is recognised that the competing concepts of equilibrium and non-equilibrium dynamics need to be integrated. Furthermore, the role of environmental variables as vegetation driving factors has long been ignored in the discussion on grazing effects on ecosystems. Present thesis, examines the dependence of plant communities on environmental in particular site-ecological conditions in three ecosystems of Western Mongolia established along a precipitation gradient to detect the vegetation-driving ecological factors involved. Furthermore, grazing impact is exemplary assessed in a desert steppe at additional spatial scales of plant communities and population. At the landscape level, a classification of plant communities in dependence on environmental conditions is carried out. Additionally, the investigations focused on the impact of grazing on soil and on the occurrence of grazing-mediated plant communities. Data were sampled along an altitudinal gradient between 1150 m to 3050 m a.s.l. from arid lowland with desert steppe via semi-arid mountain steppe to humid alpine belt. Within each altitudinal belt, data sampling was carried out along grazing gradients, established from grazing hot spots to areas distant from them. By means of an environmentally based vegetation classification, factors with highest explanation values for largest variation in vegetation were identified and considered as most responsible for vegetation patterns. To validate and affirm the classification, three different statistical methods are applied: environmentally adjusted table work of vegetation relevés supported by cluster analysis of species distribution, detrended correspondence analysis of vegetation data separately from environmental data, and the principle component analysis of only environmental data. Vegetation-driving factors change along the altitudinal gradient from abiotic forces in the desert steppe, as e.g. altitude and soil texture, to abiotic and biotic forces in the alpine belt represented by soil texture, soil nutrients and grazing. Vegetation and soil of all ecosystems respond to grazing but with different patterns and to a different extent. While desert steppe does not indicate grazing communities, mountain steppe demonstrates grazing communities at fertilised sites and alpine belt at nutrients depleted sites. Thus, the grazing sensitiveness of the ecosystems is assumed to be linked with plant productivity and the role of vegetation as site-determining factor (Chapter 2). To examine grazing impact at lower spatial scales on desert steppe as the ecosystem with lowest grazing sensitiveness at the landscape scale, at community scale the total number of species, the total vegetation cover, the percentage of annual species, the cover of annual species, and properties of soil nutrient along gradients of grazing intensity within three different communities were assessed. Vegetation parameters respond to grazing in different ways, and the responses of the same parameters vary between plant communities. Correlations with grazing intensity indicate only partly statistical significance. Significant correlations of grazing intensity with concentrations of soil nutrient point to eutrophication in two communities. A comparison of vegetation and soil properties refers to a greater indirect influence of grazing via increased soil nutrients than the direct effect on vegetation (Chapter 4). At the population level, data about stand density, aboveground biomass, individual plant weight, and the proportion of flowering plants of the dominant dwarf semi-shrub Artemisia xerophytica were collected along a grazing gradient. Soil data were used to distinguish between grazing and edaphic influences. All parameters of Artemisia xerophytica reflect the assumed gradient of grazing intensity up to 800 m distance from the grazing hot spot. As grazing pressure decreases, plant density and total biomass per plot increase. The average shrub weight, an indicator of plant vitality, is related to both: distance from the grazing hot spot and stand density, which may be explained by additional intraspecific competition at higher densities. At a longer distance, these effects are masked by variations in soil parameters determining water availability, leading to quite similar degradation forms. These results are in contrast to other studies carried out at the scale of plant communities which did not detect significant changes along a grazing gradient. One explanation is the different map scale: the study took place only within a single plant community comparing populations of one species (Chapter 3). The comparative study demonstrates that even arid desert steppes of western Mongolia display equilibrial and non-equilibrial properties, depending on the observational scale: while no grazing mediated plant communities could be identified at the landscape scale as predicted by the non-equlilibrium model, at the community level vegetation parameters imply an intermediate position between equilibrium and non-equilibrium system. At the population level, the results clearly reflect the grazing gradient as predicted by the equilibrium model (Chapter 4). As a consequence, the assessment of vegetation dynamics and grazing impact in rangelands requires a multiple-scale approach that duly considers different vegetation properties responding differently to grazing, climatic and edaphic variability at different spatial scales. It is further suggested, that future research should draw comparisons between landscapes that co-evolved with herbivory, and those that did without (Chapter 4).
A slice is an intersection of a hyperplane and a self-similar set. The main purpose of this work is the mathematical description of slices. A suitable tool to describe slices are branching dynamical systems. Such systems are a generalisation of ordinary discrete dynamical systems for multivalued maps. Simple examples are systems arising from Bernoulli convolutions and beta-representations. The connection between orbits of branching dynamical systems and slices is demsonstrated and conditions are derived under which the geometry of a slice can be computed. A number of interesting 2-d and 3-d slices through 3-d and 4-d fractals is discussed.
We present classical and hybrid modeling approaches for genetic regulatory networks focusing on promoter analysis for negatively and positively autoregulated networks. The main aim of this thesis is to introduce an alternative mathematical approach to model gene regulatory networks based on piecewise deterministic Markov processes (PDMP). During somitogenesis, a process describing the early segmentation in vertebrates, molecular oscillators play a crucial role as part of a segmentation clock. In mice, these oscillators are called Hes1 and Hes7 and are commonly modeled by a system of two delay differential equations including a Hill function, which describes gene repression by their own gene products. The Hill coefficient, which is a measure of nonlinearity of the binding processes in the promoter, is assumed to be equal to two, based on the fact that Hes1 and Hes7 form dimers.However, by standard arguments applied to binding analysis, we show that a higher Hill coefficient is reasonable. This leads to results different from those in literature which requires a more sophisticated model. For the Hes7 oscillator we present a system of ordinary differential equations including a Michaelis-Menten term describing a nonlinear degradation of the proteins by the ubiquitinpathway. As demonstrated by the Hes1 and Hes7 oscillator, promoter behavior can have strong influence on the dynamical behavior of genetic networks. Since purely deterministic systems cannot reveal phenomenons caused by the inherent random fluctuations, we propose a novel approach based on PDMPs. Such models allow to model binding processes of transcription factors to binding sites in a promoter as random processes, where all other processes like synthesis, degradation or dimerization of the gene products are modeled in deterministic manner. We present and discuss a simulation algorithm for PDMPs and apply it to three types of genetic networks: an unregulated gene, a toggle switch, and a positively autoregulated network. The different regulation characteristics are analyzed and compared by numerical means. Furthermore, we determine analytical solutions of the stationary distributions of one negatively, and three positively autoregulated networks. Based on these results, we analyze attenuation of noise in a negative feedback loop, and the question of graded or binary response in autocatalytic networks.
The six extraocular muscles (EOMs) are arranged around the eyeball as agonist-antagonist pairs performing the eye movements. The EOMs comprise a distinct muscle group that is fundamentally different from other skeletal muscle, which is reflected on many levels, such as functionality, anatomy as well as in their molecular make-up. Physiologically EOMs are considered superfast, high endurance muscles that are continuously active. In addition, EOMs contain unusual slow-tonic fibers that share features with amphibian and avian slow-tonic fibers. EOMs also express slow/cardiac isoforms of proteins and genes along with the typical isoforms of fast muscle fibers. Another striking hallmark of EOM is their differential involvement in a number of diseases. For instance, EOMs are preferentially spared in Duchenne Muscular Dystrophy (DMD). DMD is the most common fatal, genetic disease in males clinically characterized by progressive muscle wasting. Mutations in the dystrophin gene result in a destabilization of the muscle membrane causing muscle fiber damage. While all other skeletal muscles deteriorate the EOMs remain morphologically and functionally healthy. In the pathogenesis of DMD elevated Ca2+ levels are believed to be an early event and it has been shown that EOMs are protected from pharmacologically induced Ca2+ damage. The goal of this study was to characterize the spared EOMs, in particular their Ca2+ homeostasis, in the context of DMD pathology to reveal new potential therapeutic targets for the disease. A combination of physiological, molecular and biochemical methods was used to investigate the Ca2+ homeostasis of EOMs to demonstrate clear differences compared with the fast limb muscle tibialis anterior (TA). Ca2+ handling of stimulated cultured EOM myotubes suggested more efficient Ca2+ removal from the cytoplasm after induced Ca2+ influx compared with cultured myoblasts from TA. Subsequent mRNA and protein expression analyses of myoblasts and adult muscle tissue revealed high expression levels of many key Ca2+ regulating and buffering proteins in rodent EOMs compared with TA. Among these Ca2+ proteins were slow/cardiac proteins, which normally are not found in fast muscles. For instance, the sarcoplasmic Ca2+ ATPase SERCA2 was elevated along with its regulator phospholamban (PLN). Further, PLN was preferentially endogenously phosphorylated at Thr17 suggesting continuous activation of SERCA2 and possibly the fast isoform SERCA1, the main Ca2+ pumps responsible for removing Ca2+ from the cytoplasm after muscle contraction. Furthermore, Ca2+ buffers, such as calsequestrin (CASQ2) and parvalbumin (PARV) were elevated. These results suggest that EOMs are endowed with a unique and superior Ca2+ homeostasis that facilitates efficient Ca2+ buffering and removal from the cytoplasm. This is in agreement with their continuous and fast activation cycles, as well as with a potential protective mechanism in prevention of Ca2+ overload in DMD. The extreme activity patterns of EOM suggested that a high activity of store-operated Ca2+ entry (SOCE) plays a critical part to replenish Ca2+ for rapid and continuous cycles of contractions. To extend the data on general Ca2+ homeostasis and because of possible implications of store-operated Ca2+ influx and other Ca2+ influx pathways in DMD, the expression patterns of group 1 transient receptor potential (TRP) channels and the proteins Orai1 and STIM1 were studied. The TRP channels, TRPC1, TRPC6 and TRPV4 channel proteins in addition to STIM1 showed higher expression in EOM compared with TA. High TRPC1, TRPV4 and STIM1 levels could play a significant role in the high fatigue resistance, muscle differentiation and SOCE in EOM. In addition, tissue from the mdx mouse model of DMD was investigated. The only channels differentially expressed in mdx EOM compared with normal EOM were TRPM4 and TRPM7 (decreased in mdx EOM) and TRPV4 (increased in mdx EOM). Although, these changes in mdx EOM were of small magnitude, they could point toward subtle compensatory changes related to the disease process. In general, EOMs seem to be unaffected by the disease and inherently protected. In conclusion, the results in this thesis have improved the understanding of the Ca2+ homeostasis in EOMs and suggest that EOM may be better able to prevent prolonged elevation of cytoplasmic Ca2+ levels. These data may help to design new therapeutic approaches targeting Ca2+ handling proteins to ameliorate muscular dystrophy.
In the present thesis, a systematic study of beam driven Alfvén eigenmodes in high-density and low-temperature plasmas of the W7-AS stellarator is performed. The device went out of operation in 2002 and the study is based on stored experimental data. Alfvén instabilities can roughly be divided into ideal MHD Alfvén eigenmodes and those existing due to kinetic effects. The spectrum of ideal MHD Alfvén waves in toroidal fusion devices consists of a continuum of stable waves that are strongly localized. Weakly damped, discrete eigenmodes can exist in gaps of the continuous spectrum which are formed by plasma inhomogeneities and the coupling of Alfvén continua. This allows an identification of ideal MHD Alfvén eigenmodes in terms of their frequency and mode numbers. Kinetic effects can modify this spectrum and cause additional types of eigenmodes, the kinetic Alfvén eigenmodes (KAE) and energetic particle modes (EPM). The goal of this thesis is twofold: (I) identification and description of fast particle driven Alfvén instabilities in W7-AS, and (II) study of energetic particle losses induced by Alfvén instabilities. The reconstruction of the ideal MHD plasma equilibrium for each discharge with sufficient accuracy is the very foundation of all subsequent steps. This is achieved, based on measured plasma parameter profiles that are further refined by validating them to the measurements of other, independent plasma diagnostics. The applied scheme is inspired by an approach of Integrated Data Analysis (IDA) to combine different diagnostic data and provide combined uncertainties. After mode number analysis and eigenmode identification, the theoretically expected, linear growth rate of the instability is calculated where possible, and the various contributions of the fast particle drive to the instability of the mode are identified. Alfvénic activity recorded by the Mirnov diagnostic is analyzed, which consists of a set of spatially distributed coils that measure magnetic fluctuations. On W7-AS, the probes are arranged in three poloidal arrays at different toroidal positions. The spacing between the probes is non-equidistant. In addition, the signals of one probe array are digitized with a different sample rate. These characteristics prohibit the straight-forward use of standard tools available for harmonic analysis. Instead, a new tool has been developed and thoroughly tested. It is a multi-dimensional extension of the Lomb periodogram, able to provide reliable time-resolved frequency and mode number spectra in the case of uneven datapoint spacing. Numerical studies of this periodogram show a good performance with respect to mode number resolution given the low number of available probes, and robustness against perturbations of the signal. Only two of the probe arrays can be used for the analysis of eigenmodes with frequencies >70 kHz, such that for high-frequency phenomena insufficient information about the mode numbers is available. A total of 133 different Alfvén eigenmodes is studied in discharges from different experimental campaigns. A restriction to discharges from various high-beta campaigns with neutral beam heating is required to allow for a realistic reconstruction of plasma equilibrium and velocity distribution functions of energetic particles. The discharges are characterized by high density, ne = 5 x 1019 m-3 to 2.5 x 1020 m-3 at relatively low temperatures of Te = Ti = 150 ... 600 eV. Alfvén eigenmodes often appear transiently in the startup phase of these discharges, where density and heating power are being ramped up. Occasionally, Alfvén eigenmodes are seen in the stationary, high-beta phase in the presence of considerable neutral beam heating. Most of the Alfvén eigenmodes are successfully classified as ideal MHD eigenmodes. 19 global, 47 toroidicity-induced and 8 ellipticity-induced Alfvén eigenmodes (GAEs, TAEs, and EAEs, respectively) are unambiguously identified by their mode numbers and frequencies. Excellent agreement between experimentally observed mode number spectra and theoretically calculated eigenmode structure is shown for a TAE example. Additional 13 events are found to have frequencies inside the EAE gap and could possibly be EAEs. Evidence for high-frequency Alfvén eigenmodes (mirror- and helicity-induced Alfvén eigenmodes) is seen, but can not be proven rigorously due to uncertain mode numbers and the complexity of the Alfvén continuum. The remaining 41 Alfvén eigenmodes can not be classified to be one of the above cases. Reasons are either high frequencies, mode numbers obscured by far-field effects, or mode numbers that could not be related to ideal MHD Alfvén eigenmodes. A selection of these shows indications of strong non-linear wave-particle interactions and are assumed to be EPMs. Kinetic Alfvén eigenmodes are not expected to exist in the experimental conditions that were studied. The radially resolved velocity distribution function is used to describe the parameter regimes in which the modes are observed in terms of the dimensionless parameters vb/vA (beam velocity normalized to the Alfvén velocity) and ßfast/ßth, where beta is the ratio of plasma pressure to magnetic pressure. The first parameter describes through which of the possible resonance velocities particles can interact with the eigenmode. A peculiarity of the fast particle dynamics in fusion devices is that they can resonantly interact with Alfvén eigenmodes through sideband resonances even if v < vA. The second parameter describes the energy content of the destabilizing fast particle population compared to the potentially stabilizing thermal plasma component. These parameters contain relevant information about the instability of an eigenmode and such diagrams are given for all observed modes. In addition to that, the expected linear growth rate of gap modes is calculated based on a theoretical model that extends the ideal MHD by a perturbative, drift-kinetic description of the energy exchange between waves and circulating particles, neglecting the effects of trapped particles. For the discharges under consideration the thermal electron speed is comparable to vA and the electrons provide a significant Landau damping contribution. Due to strong density gradients near the plasma boundary in most of the discharges, the thermal ions can provide a small drive via the spatial inhomogeneity which does not overcome the electron damping, however. The drive by spatial inhomogeneity of thermal ions requires a certain propagation direction of the mode and is equally stabilizing for opposite mode numbers. The fast particles also contribute to the growth rate via spatial inhomogeneity, velocity gradients and velocity anisotropy terms are negligible in W7-AS. Most of the observed GAE or EAE modes have negative mode numbers, which correspond to a propagation direction for which the spatial inhomogeneity of thermal and beam ions is predicted to be stabilizing. A fast particle drive of these modes is not confirmed, whereas the TAEs are found to be strongly destabilized by neutral beam injection. The distribution of plasma parameters for discharges showing TAEs in terms of the dimensionless stability parameters suggests an instability threshold that is qualitatively confirmed by an exploration of the parameter space with the theoretical model. Wave-induced, resonant losses of energetic ions scale linearly with the wave amplitude. To identify them, correlations between ion loss probe signals and wave amplitudes are searched, where correlation times in the order of the slowing-down time of energetic particles are expected. Significant correlations can be established only exceptionally for 3 of the identified ideal MHD Alfvén eigenmodes. Those Alfvén eigenmodes, however, which are assumed to be EPMs frequently show severe losses of energetic ions that are visible in the time traces of the plasma energy as well.
Technological advances in light microscopy have always gone hand in hand with unprecedented biological insight. For microbiology, light microscopy even played a founding role in the conception of the entire discipline. The ability to observe pathogens that would otherwise evade human observation makes it a critical necessity and an indispensable tool to infectious disease research. Thus, the aim of this thesis was to optimize, extend, and functionally apply advanced light microscopy techniques to elucidate spatio-temporal and spatio-morphological components of bacterial and viral infection in vitro and in vivo.
Pathogens are in a constant arms race with the host’s immune system. By finding ways to circumvent host-mediated immune responses, they try to evade elimination and facilitate their own propagation. The first study (publication I) demonstrated that the obligate intracellular pathogen Coxiella burnetii is not just able to infect natural killer (NK) cells, but is actually capable of surviving the harsh degradative conditions in the cytotoxic lymphocyte’s granules. Using live-cell imaging of reporter-expressing Coxiella burnetii, the transient NK cell passage was closely monitored to provide detailed spatio-temporal information on this dynamic process in support of a range of static analyses. Bacterial release from NK cells was pinpointed to a time frame between 24 to 48 hours post-infection and the duration of release to about 15 minutes.
The second approach (publications II-V) aimed at shedding light on the greater spatio-morphological context of virus infection. Thus far, most studies investigating the distribution or tropism of viruses in vivo have used conventional immunohistochemistry in thin sections. Omitting the native spatial context of the infection site in vivo inherently bears the risk of incomplete description. While the microscopic tools and sample preparation protocols needed for volumetric 3D immunofluorescence imaging have recently been made available, they had not gained a foothold in virus research yet. An integral part of this thesis was concerned with the assessment and optimization of available tissue optical clearing protocols to develop an immunofluorescence-compatible 3D imaging pipeline for the investigation of virus infection inside its intact spatio-morphological environment (publication II). This formed the basis for all subsequent volumetric analyses of virus infection in vivo presented here. Consequently, this thesis provided a valuable proof of concept and blueprints for future virus research on the mesoscopic scale of host-pathogen interactions in vivo (publications II-V), using rabies virus (RABV; publications II-IV) and the newly-emerged severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2; publication V) as infection models for the nervous system and the respiratory tract, respectively.
Applying and further improving this volumetric 3D imaging workflow enabled unprecedented insights into the comprehensive in vivo cell tropism of RABV in the central (CNS) (publication III) and peripheral nervous system (PNS) (publication IV). Accordingly, differential infection of CNS-resident astrocytes by pathogenic and lab-attenuated RABV was demonstrated (publication III). While either virus variant showed equal capacity to infect neurons, as demonstrated by quantitative image analysis, only pathogenic field RABVs were able to establish non-abortive infection of astrocytes via the natural intramuscular inoculation route. A combined 3D LSFM-CLSM workflow further identified peripheral Schwann cells as a relevant target cell population of pathogenic RABV in the PNS (publication IV). This suggested that non-abortive infection of central and peripheral neuroglia by pathogenic RABV impairs their immunomodulatory function and thus represents a key step in RABV pathogenesis, which may contribute significantly to the establishment of lethal rabies disease.
Finally, utilizing the full volumetric acquisition power of LSFM, a further refined version of the established 3D imaging pipeline facilitated a detailed mesoscopic investigation of the distribution of SARS-CoV-2 in the respiratory tract of the ferret animal model (publication V). Particularly for this newly-emerged pathogen of global concern, in-depth knowledge of host-pathogen interactions is critical. By preserving the complete spatio-morphological context of virus infection in the ferret respiratory tract, this thesis provided the first specific 3D reconstruction of SARS-CoV-2 infection and the first report of 3D visualization of respiratory virus infection in nasal turbinates altogether. 3D object segmentation of SARS-CoV-2 infection in large tissue volumes identified and emphasized a distinct oligofocal infection pattern in the upper respiratory tract (URT) of ferrets. Furthermore, it corroborated a preferential replication of SARS-CoV-2 in the ferret URT, as only debris-associated virus antigen was detected in the lower respiratory tract of ferrets, thus providing crucial information on the spatial distribution of SARS-CoV-2.
The collisionless tearing mode is investigated by means of the delta-f PIC code EUTERPE solving the gyrokinetic equation. In this thesis the first simulations of electromagnetic non-ideal MHD modes in a slab geometry with EUTERPE are presented. Linear simulations are carried out in the cases of vanishing and finite temperature gradients. Both cases are benchmarked using a shooting method showing that EUTERPE simulates the linearly unstable tearing mode to a very high accuracy. In the case of finite diamagnetic effects and values of the linear stability parameter Delta of order unity analytic predictions of the linear dispersion relation are compared with simulation results. The comparison validates the analytic results in this parameter range. Nonlinear single-mode simulations are performed in the small- to medium-Delta range measuring the dependency of the saturated island half width on the equilibrium current width. The results are compared with an analytic prediction obtained with a kinetic electromagnetic model. In this thesis the first simulation results in the regime of fast nonlinear reconnection~(medium- to high-Delta range) are presented using the standard gyrokinetic equation. In this regime a nonlinear critical threshold has been found dividing the saturated mode from the super-exponential phase for medium-Delta values. This critical threshold has been proven to occur in two slab equilibria frequently used for reconnection scenarios. Either changing the width of the equilibrium current or the wave number of the most unstable mode makes the threshold apparent. Extensive parameter studies including the variation of the domain extensions as well as the equilibrium current width are dedicated to a comprehensive overview of the critical threshold in a wide range of parameters. Additionally, a second critical threshold for high-Delta equilibria has been observed. A detailed comparison between a compressible gyrofluid code and EUTERPE is carried out. The two models are compared with each other in the linear regime by measuring growth rates over wave numbers of the most unstable mode for two setups of parameters. Analytical scaling predictions of the dispersion relation relevant to the low-Delta regime are discussed. Employing nonlinear simulations of both codes the saturated island half width and oscillation frequency of the magnetic islands are compared in the small-Delta range. Both models agree very well in the limit of marginal instability and differ slightly with decreasing wave vector. Recently, the full polarisation response in the quasi-neutrality equation was implemented in EUTERPE using the Padé approximation of the full gyrokinetic polarisation term. Linear simulation results including finite ratios of ion to electron temperature are benchmarked with the dispersion relation obtained from a hybrid model. Finite temperature effects influence the saturated island width slightly with increasing ion to electron temperature ratio which has been verified by both models.
Forests influence the climate of our Earth and provide habitat and food for many species and resources for human use. These valuable ecosystems are threatened by fast environmental changes caused by human-induced climte change. Negative growth responses and higher tree mortality rates were associated with increasing physiological stress induced by global warming. Especially boreal forests at high latitudes in the arctic region are threatened, a region predicted to undergo the highest increase in temperature during the next decades. Therefore, it is important to assess the adaptation potential in trees. For this purpose, I studied natural populations of white spruce (Picea glauca (Moench) Voss) in Alaska. In this thesis, I present three scientific papers in which my co-authors and I studied the phenotypic plasticity and genetic basis of tree growth, wood anatomy and drought tolerance as well as the genetic structure of white spruce populations in contrasting environments. We established three sites representing two cold-limited treelines and one drought-limited treeline with a paired plot design including one plot located at the treeline and one plot located in a closed-canopy forest, respectively. Additionally, the study design included one forest plot as reference. Within the entire project, in total 3,000 trees were measured, genotyped and dendrochronological data was obtained. I used several approaches to estimate the neutral and adaptive genetic diversity and phenotypic plasticity of white spruce as a model organism to explore the adaptation potential of trees to climate change.
In the first chapter, I combined neutral genetic markers with dendrochronological and climatic data to investigate population structure and individual growth of white spruce. Several individual-based dendrochronological approaches were applied to test the influence of genetic similarity and microenvironment on growth performance. The white spruce populations of the different sites showed high gene flow and high genetic diversity within and low genetic differentiation among populations, rather explained by geographic distance. The individual growth performances showed a high plasticity rather influenced by microenvironment than genetic similarity.
In the second chapter, I investigated the populations of the drought and cold-limited treeline sites to decipher the underlying genetic structure of drought tolerance using different genotype-phenotype association analyses. Based on tree-ring series and climatic data, growth declines caused by drought stress were identified and the individual reaction to the drought stress event was determined. A subset of 458 trees was genotyped, using SNPs in candidate genes and associated with the individual drought response. Most of the associations were revealed by an approach which took into account small-effect size SNPs and their interactions. Populations of the contrasting treelines responded differently to drought stress events. Populations further showed divergent genetic structures associated with drought responsive traits, most of them in the drought-limited site, indicating divergent selection pressure.
In the third chapter, my co-authors and I studied xylem anatomical traits at one of the cold-limited treeline sites to investigate whether genetic or spatial grouping affected the anatomy and growth of white spruce. Annual growth and xylem anatomy were compared between spatial groups and between genetic groups and individuals. Overall, wood traits were rather influenced by spatial than genetic grouping. Genetic effects were only found in earlywood hydraulic diameter and latewood density. Environmental conditions indirectly influenced traits related to water transport.
In conclusion, white spruce showed a high genetic diversity within and a low genetic differentiation among populations influenced by high gene flow rates. Genetic differences among populations are rather caused by geographical distance and therefore genetic drift. Differing selection pressure at the treeline ecotones presumably lead to divergent genetic structures underlying drought-tolerant phenotypes among the populations. Thus, adaptation to drought most likely acts on a local scale and involves small frequency shifts in several interacting genes. The identified genes with adaptive growth traits can be used to further exlore local adaptation in white spruce. Tree growth and wood anatomical traits are rather influenced by the environment than genetics and showed a high phentoypic plasticity. The high genetic diverstiy and phenotypic plasticity of white spruce may help the species to cope with rapid environmental changes. Still, additional work is needed to further explore adaptation processes to estimate how tree species reacted to rapid climate change. The presented thesis shed some light on the adaptation potential of trees by the example of white spruce using several approaches.
Objective: To compare the effectiveness and complications of intraligamentary anesthesia
(ILA) with conventional inferior alveolar nerve block (IANB) during injection and dental
treatment of mandibular posterior teeth.
Materials and Methods: In this randomized, prospective clinical trial, 72 patients (39 males, 33
females) patients scheduled for dental treatment of mandibular posterior teeth, were randomly
allocated to ILA group (n=35) received ILA injection or IANB group (n=37) received the
conventional IANB. Our primary outcome was to assess pain and stress (discomfort) during the
injection and dental treatment, using the Numeric Rating Scale (NRS) from 0 to 10 (0 = no
pain, 10= the worst pain imaginable). Whereas; recording 24 hours postoperative complications
were our Secondary outcomes.
Results: Patients in ILA group reported significantly less pain during injection when compared
with IANB group (p=0.03). While pain during dental treatment was similar in both groups
(p=0.2). Patients in both groups also reported similar low values of discomfort during treatment
(p= 0.7). Although no signs of nerve contact or any other postoperative complications were
observed, five patients in IANB group (none in ILA group) reported temporary irritations
Conclusion: This study showed equivalent effectiveness of both intraligamentary anesthesia
and conventional inferior alveolar nerve block, for pain control during routine dental treatment
of mandibular posterior teeth. Nevertheless, ILA showed significantly less pain during
injection. No major postoperative complications in both groups were observed.
Clinical Relevance: ILA could be considered as an effective alternative for routine dental
treatment.
Ribozymes for Aminoacylation
(2012)
Aminoacyl-tRNA synthetases (aaRS) are at the heart of modern translation, catalyzing the accurate biosynthesis of aminoacyl-tRNAs. According to the RNA world hypothesis, the early translation system should have aminoacylation ribozymes for RNA aminoacylation. For this, an aaRS ribozyme system, consisting of the KK13 ribozyme and the C3a ribozyme was successfully designed, which can perform both amino acid activation and aminoacyl transfer reaction. Generation of such aminoacylation ribozyme system would fill up the gap between the RNA world and the modern biological world. In addition, two types of diversified aminoacylation ribozymes, symmetrical ribozymes and self-assembling ribozymes were successfully developed, which may have great meaning in the origin of life.
The glioblastoma multiforme (GBM) not only presents the most common tumor of the central nervous system in adults, it is also the most aggressive brain tumor. Although patients suffering from GBM standardly receive a combination of multiple treatments including surgery, radiotherapy and chemotherapy, its prognosis is still poor with a median survival time of only 12-15 months. Therefore, new and effective treatment methods are urgently needed.
A signaling molecule which is both involved in proliferation, migration and invasion of a broad range of healthy and malignant cells is the lipid mediator sphingosine-1-phosphate (S1P). Previous studies have confirmed that sphingosine-1-phosphate (S1P) receptor 1 (S1PR1) is involved in the regulation of proliferation, invasion, metastasis, vascular maturation and angiogenesis of GBM cells, and is closely related to the occurrence and development of tumors. Thus, ACT-209905 (provided by Actelion Pharmaceuticals) as a selective S1PR1 modulator was applied to gain insights into the molecular processes activated by S1PR1 in GBM cells using two human (LN18, U87MG) and one murine (GL261) GBM cell line.
In our in vitro cell viability analyses, we found that ACT-209905 significantly reduced viability of LN18 cells in a concentration dependent manner. A combined administration of ACT-209905 with S1PR2 inhibitors (Compound 16, Compound 16ME – both provided by ONO Pharmaceuticals, and JTE-013 – commercially available) showed a stronger effect than the single administration demonstrating that both S1PR1 and S1PR2 are involved in growth of GBM cells and may interact with each other. Our results also demonstrated that ACT-209905 can induce apoptosis in GBM cells since caspase 3 activity was induced by the S1PR1 modulator which might therefore play an important role in inhibiting the proliferation of GBM cells. Further, we found a significant inhibitory effect of ACT-209905 on the migration and invasion of LN18 and U87MG GBM cells arguing for a participation of S1PR1 signaling in migration and invasion of GBM cells, too. Stimulation of S1P receptors results in the activation of several kinases such as AKT1 and ERK1/2, correspondingly our immunoblot analyses showed a strong activation of both kinases by S1P which was reduced by ACT-209905 in LN18 cells but not in GL261 cells suggesting that different pathways are activated by S1P in these GBM cell lines. Further studies have to be performed to clarify the role of AKT1 and ERK1/2 in the inhibitory effects of ACT-209905 on GBM proliferation, migration and invasion.
Currently, GBM stem cells are discussed as a reason for resistance against the radiochemotherapy and the recurrence of the tumor. Our immunoblot analyses showed that Nestin and CD133, two marker proteins for GBM stem cells, were higher expressed in GBM cells treated with ACT-209905 compared to control or S1P treated LN18 cells. Further investigations in the future might contribute to the elucidation of an involvement of the S1P receptors in the stem cell behavior of GBM cells. Paradoxically to the up-regulation of CD133 and Nestin by ACT-209905, treatment of LN18 stem-like neurospheres with ACT-209905 showed a significant cytotoxic effect of the compound which was even more pronounced in the stem-like neurosphere cells compared to the adherent parental LN18 cells.
Overall, the studies of this work improve our understanding of the complex mechanisms of S1P signaling in GBM cells and might drive the development of its pharmacological modulation as a new therapeutic principle in GBM. Furthermore, an extended knowledge about the molecular effects of ACT-209905 on GBM cells will broaden the understanding for possible future applications and clinical indications.
With the aim to discover and create suitable biocatalysts for the synthesis of chiral amines in a faster and more efficient way, this thesis includes protein engineering studies (Article I), explores transaminase substrate specificities (Articles II and IV), and an ultrahigh-throughput growth system-based for the directed evolution of amine-forming enzymes (Article III).
The protein engineering studies described in Article I deal with the creation of a (R)-amine transaminase activity in the α-amino acid transaminase scaffold to expand our knowledge of the evolutionary relationship between amine transaminase and α-amino acid transaminase. Article II describes the broadening of the limited substrate scope of transaminases to enable the conversion of bulky substrates. In Article III, a growth selection system is described for an ultra-high throughput screening strategy to accelerate the identification of desired mutants, which can be widely applied to the directed evolution of amine-forming enzymes.
Global climate change is occurring all over the world, but in the Arctic the climate is changing more rapidly and drastically than in many other parts of our planet. Many species that are already at their climatic limit need to adapt to recent climate conditions or migrate in order to not go extinct. The possibilities of adaption include phenotypic plasticity and adaptation to various extents. This is also the case for white spruce P. glauca, which belongs to the conifers and thus in the largest group of gymnosperms still living today. Among the approx. 600 extant conifer species white spruce is one of the most widespread trees in North American boreal forests. Its range extends from 69° N in the Canadian Northwest Territories to the Great Lakes at about 44° N, where it occurs from sea level to an altitude of about 1520 m (Burns and Honkala, 1990). Site related, climate-dependent differences in white spruce reproduction can be seen as a strategy to survive under the harsh climatic conditions at Alaska's treelines: Besides sexual reproduction, the vegetative propagation occurs in the white spruce as an additional reproductive mechanism. This can be realized by "layering" when the lower branches of the tree crown touch the ground and develop roots to later grow as a separate individual with or without a connection to the mother tree. Known as other mechanisms of vegetative propagation are also the rooting of fallen trees which were not completely uprooted, and the "root suckering", in which new shoots sprout from the roots of the tree. However, the latter was not yet observed in the genus Picea. With the help of short, repetitive, non-coding sequences in the genome, which are therefore not subject to selection and are called microsatellites, these clones can be determined by genotyping.
For this purpose, using different polymorphic microsatellites, an individual multilocus genotype is created for each tree, by means of which it can be compared with all other trees of the same species.
In the first part of this work (article I), the occurrence of clones in three study areas at Alaskan treelines are examined and the reasons for their appearance in variable numbers are discussed. For this purpose, 2571 white spruces (P. glauca) were genotyped and their position was determined via differential GPS in the field. The percentage of clonal trees is higher in areas with harsh climatic conditions and correlates with the height of the lowest branches of the tree crown. This suggests that the vegetative propagation of white spruce is a backup strategy for times when climatic conditions hamper sexual reproduction. The correlation between clone numbers and tree crown height suggests "layering" as the main mechanism for cloning whereas selection for vegetative reproduction seems to be very unlikely shown by the results for genetic differentiation between the clonal and the singleton trees in this study.
In the second part of this work (articles II and III), the influence of environmental factors and phenotypic traits on the mycobiome of the needles (including all fungi living on (epiphytic) and in (endophytic) the needles) in our study areas in Alaska was investigated. The mycobiome of the white spruce needles was chosen as a proxy for the parasite infection rate by fungi and thus serves as a fitness parameter. For this purpose, all epiphytic and endophytic fungal species were analyzed by a metabarcoding analysis.
In article II, 48 trees of one study area at Alaska’s northern treeline (Brooks Range) were examined for differences in mycobiome due to genetic differentiation, phenotypic characteristics and / or habitat characteristics. The trees used for this study were sampled from two adjacent plots on a south-facing mountain slope with an elevation gradient from 875 to 950 meters above sea level. It could be shown that, in contrast to the trees genotype, the height above sea level, the mountain slope, as well as the height and age of the trees have a significant impact on the mycobiome. The genetic differentiation between the tree individuals, however, showed no significant effect.
Based on article II we examined the mycobiome composition of a total of 96 trees in 2 plots (16 trees each) at three sites in Alaska over a distance of 500 kilometers. Additionally, we sampled needles of two different ages for each tree (current year and three years old needles) summing up to 192 samples in total. The incentive of this study (article III) was to investigate the influence of origin and age of spruce needles on their mycobiome and if there is a genetic predisposition that is related to the fungal species community. In addition, the sampling design was improved by collecting needles from all four orientations (North, South, East and West) and sampling trees at a standardized distance to each other to avoid systematic errors. Comparable to article II the influence of the trees genetics on the species community of the epiphytic and endophytic fungi of the white spruce needles seems to be very unlikely. In contrast, a significant influence of the geographic origin and the needle age on the species structure of the needle inhabiting fungal species was found. The phenotypic tree traits height and dbh (diameter at breast height) had only minor influence and did in fact explain less than 2% of the mycobiome variance. Using Illumina sequencing, 10.2 million reads from the nucleotide sequence between the internal transcribed spacer (ITS) genes could be obtained, which yielded in 1575 ribotypes (called operational taxonomic unit, OTU) for the fungi. These were compared with a reference database to compare and assign them to known fungal species. For example, 942 OTUs with >95% similarity could be identified as known species, with 1975 samples identified on genus level and 2683 when determined to family level. The most pronounced difference between the two studies (article II and III) were due to the fungal species of the class of Pucciniomycetes, more specifically the genus Chrysomyxa which belongs to the rust fungi and is plant pathogenic. In the study of article II (sampling in 2012), Pucciniomycetes accounted for only a minor portion of the assigned DNA sequences. In the second study (article III, sampling in 2015) they accounted for more than half of all basidiomycetes found, which in turn contain 20.0% of all DNA sequences, the second largest phylum found beside Ascomycetes (51.4%).
Mass spectrometry-based Proteome analysis of porcine cells infected with African swine fever virus
(2023)
ASFV, a highly contagious, pathogenic and lethal pathogen of swine, poses a major threat to domestic and wild suids worldwide as neither vaccines nor treatments are available. Compared to other well-characterized similarly complex viruses like herpesviruses or adenoviruses, the understanding of ASFV biology is poor.
To improve the understanding of ASFV biology, following the establishment of a robust protocol for the isolation of primary monocyte-derived porcine macrophages (moMΦ) and their infection with ASFV for mass spectrometry (MS)-based proteome analysis was performed.
Under both conditions, naïve and infected, the isolated cells showed cell type-specific characteristics like phagocytosis and antigen presentation and protein expression patterns, including the expression of swine leucocyte antigens and CD markers. Furthermore, moMΦ could be reproducibly infected with ASFV isolates of different genotypes and pathogenicity.
The ASFV protein expression patterns in moMΦ correlate well with those observed in established cell lines at transcript and protein level. The expression of 27 ASFV proteins was confirmed at the protein level. Among them, 9 members of multi-gene families (MGF) and 12 novel open reading frames (nORFs) were recently predicted based on transcription start site mapping.
The direct comparison of closely related ASFV genotype II isolates revealed no virulence-associated protein expression patterns beyond those expected based on the genome sequences of the isolates.
Using different MS quantification strategies, it was shown that ASFV affects both static protein expression levels and protein synthesis. These changes in protein expression impact proteins and pathways known to be targeted by ASFV, including CD-markers, ER-stress and cell death pathways, and cellular antiviral responses. Beyond these observations that further validated the moMΦ infection model, novel effects of the ASFV infection on the cellular proteome were noticed.
These effects include the decreased expression levels of cathepsins, especially cathepsins D (CTSD), H (CTSH) and L (CTSL) as well as the transient activation of MAPK14/p38 prior to its strong downregulation. In addition to MAPK14/p38 further members of the MAPK14/p38 signaling pathway, like MAPKAPK2, were affected by ASFV infection.
As these modulations of the cellular proteome would in general result in decreased pro-inflammatory responses, it did stand out that the synthesis of interferon-response related genes including MX1 and ISG15 evaded the ASFV-induced global reduction of protein synthesis. In contrast, the synthesis of genes involved in RNA processing and splicing was significantly impaired. In total, the regulations of individual host proteins assessed in the context of the whole cellular proteome integrate well with each other and other cellular responses to ASFV infection and may help to improve the understanding of host-virus interactions.
Overall, this thesis provides novel insights into the expression of ASFV-encoded ORFs of different isolates and the host response to ASFV infection. It points out that the current knowledge of the ASFV coding capacity, temporal protein expression patterns, protein functionality, post-translational modifications and host interactions is still sketchy as many aspects of ASFV replication have yet to be understood. The established moMΦ-model to study ASFV infections in vitro provides a powerful tool for future applications to increase the understanding of ASFV biology.
Cerebral palsy (CP) remains one of the most common debilitating diseases in the world.
Factors such as neuromuscular incoordination, use of soft diet and delayed oral
clearance of food make maintenance of optimum oral hygiene a challenging task in
these children. The compromised oral hygiene in turn make these children highly
vulnerable to dental disease. Maintaining optimal oral/dental health in CP children is of
utmost importance as these children usually suffer from several associated general
health problems in addition to their primary condition. Poor dental health further
compromises their general health. Nevertheless, CP children often suffer from dental
diseases including dental caries more than healthy children. This underscores the need
for improvement in oral health of the CP children. The CP children are dependent on
those around them for their oral hygiene maintenance and dietary intake. CP children
spend most of their time with health care workers in special centers for them or with
their parents/care takers at home. Therefore, the attitude of special health care workers
and parents towards their dental health is of prime importance. The purpose of this
project included to determine the attitude of special health care workers towards their
dental health and oral health comprehension by parents of CP children. In addition, a
study on caries experience of CP children and associated risk factors was also completed.
The final objective was to identify various potential areas of improvement with ultimate
goal of improving dental health of the CP children.
The study involving special health care workers in a Disabled Children’s Center revealed
that oral health knowledge and practices among the workers could generally be labeled
as satisfactory, however some weak areas (such as trend towards symptom-oriented
utilization of oral health care and lack of knowledge about fluoridated water) were
identified. There is a need to enhance the workers’ knowledge in these areas.
The study involving parents of the CP children showed mixed results. Some areas of
strong oral health comprehension (such as importance of good dental health, harmful
effects of sweetened foods), others satisfactory (such as need for routine dental visits,
use of fluoride) and some weak areas (use of flavored fizzy drinks, bottled/canned juices
and sweetened/flavored milks, seeking early treatment) were identified among parents
of CP children. The results strongly indicated a need for enhanced efforts towards
improvement of oral health comprehension in the parents of the CP children.
The study about caries experience and risk factors in CP children has provided useful
information in an area where literature has been scarce. Almost all the studied children
had clinical dental caries, and most of the caries were untreated. Very few children in
the present study had optimal oral hygiene. This study confirmed the strong correlation
between high dental caries experience and poor oral hygiene. Routine dental check-up
visits and topical fluoride application clearly resulted in lower caries experience. Bottled
juices and crispy potato chips were the two predictors for high caries experience.
As stated before, the goal of the project was to identify various potential areas of
improvement in oral health attitude of special health care workers, oral health
comprehension of the parents of CP children and risk factors for dental caries in CP
children. It is contemplated that by addressing the identified weak areas, an
improvement in dental health and care of the CP children is expected. It is also expected
that the collected information will help in improvement of clinical preventive as well as
restorative services for the CP children. CP children and their parents lead a challenging
life. This project was an effort to assist these children and their parents/care takers with
ultimate goal of improving their oral health and in turn their overall quality of life.
Optomechanical (om) systems are characterized by their nonlinear light-matter interaction. This is responsible for unique dynamic properties and allows the detection of a variety of classical and quantum mechanical phenomena on a microscopic as well as on a macroscopic scale. In this work we have studied the dynamic behavior of two laser-driven om systems, the single om cell ("cavity optomechanics / membrane-in-the-middle setup") and a two-dimensional hexagonal array of these cells ("om graphene"). The first case was motivated by the possibility to detect the transition from quantum mechanics to classical mechanics directly on the basis of the dynamic behavior. For this we focus on multistability effects of the optical and mechanical degrees of freedom, that are modeled by harmonic oscillators. Our description is based on the quantum optical master equation, which takes into account the environmental interaction assuming a vanishing temperature. As a consequence of decoherence, the dynamics occur near the semiclassical limit, i.e. it is characterized by quantum fluctuations. The quantum-to-classical transition is realized formally by rescaling the equations of motion. In the classical limit, quantum fluctuations disappear and the mean field equations were evaluated by analytical and numerical methods. We found that classical multistability is characterized by stationary signatures on the route to chaos, as well as by the coexistence of single-periodic orbits for the mechanical degree of freedom. The latter point was extensively evaluated by means of a self-consistent approach. For the dynamics in the quantum regime quantum fluctuations cannot be neglected. For this purpose, the master equation was solved by means of a numerical implementation of the Quantum State Diffusion (QSD) method. Based on Wigner and autocorrelation functions, we were able to show that quantum multistability is a dynamic effect: chaotic dynamics is suppressed and there is a time-dependent distribution of the phase space volume on classical simple-periodic orbits. The results can be interpreted within a semiclassical picture, which makes use of the single QSD quantum trajectory. Accordingly, the quantum-classical transition is explained as a time-scale effect, which is determined by tunneling probabilities in an effective mean-field potential. The subject of the second part of the work is the transport of low-energy Dirac quasiparticles in om graphene, propagating as light and sound waves. For this purpose, we investigated the scattering of a plane light wave by laser-induced photon-phonon coupling planar and circular barriers. The starting point is the om Dirac equation, which results from the continuum approximation of the Hamiltonian description of the two-dimensional array near the semiclassical limit. This work was motivated by the rich and interesting relativistic transport and tunneling phenomena found for electrons in graphene, which now appear in a new way. The reason is the presence of the new spin degree of freedom, which distinguishes the optical and mechanical excitations. In this spin space, the om interaction can be understood as a potential, which in our analysis consists of a time-independent and a time-dependent sinusoidal part. For the first case of a static barrier, the transport is elastic and is characterized by stationary scattering signatures. After solving the scattering problem via continuity conditions we were able to identify different scattering regimes depending on scattering parameters. In addition to relativistic phenomena such as Klein tunneling, simple parameter variation allows to use the barrier as a resonant light-sound interconverter and angle-dependent emitter. For the oscillating barrier, the transport is inelastic and is characterized by dynamic scattering signatures. To solve the time-periodic scattering problem, we have applied the Floquet theory for an effective two-level system. As a result of the barrier oscillation, photons and phonons can get and give away energy portions in the form of integer multiples of the oscillation frequency. The interference of short (classical) and long-wave (quantum) components leads to mixing of the scattering regimes. This allows to use the barrier as a time-periodic light-sound interconverter with interesting radiation characteristics. In addition, we have argued that the oscillating barrier provides the necessary energetic conditions for detecting zitterbewegung.
The focus of the first two articles was the engineering and application of enzymes for the conversion of the bio-based resources glycerol and its oxidation product glyceraldehyde for the production of the value added product glyceric acid. Article III focuses on the cloning, exploration and engineering of a polyol dehydrogenase, which later on was used as cofactor recycling system in order to produce ε-caprolactone from cyclohexanol as presented in arti-cle IV. The following paragraphs will give a short outline of each article. ARTICLE I: ASYMMETRIC SYNTHESIS OF D-GLYCERIC ACID BY AN ALDITOL OXIDASE AND DIRECTED EVOLUTION FOR ENHANCED OXIDATIVE ACTIVITY TOWARDS GLYCEROL. GERSTENBRUCH, S., WULF, H., MUßMANN, N., O’CONNELL, T., MAURER, K.-H. & BORNSCHEUER, U. T. (2012). Appl. Microbiol. Biotechnol. 96, 1243-1252. The alditol oxidase of Streptomyces coelicolor A3(2) (AldO) was used to catalyze the oxida-tion of glycerol to glyceraldehyde and glyceric acid. The enantioselectivity for the FAD-de-pendent glycerol oxidation was elucidated and different strategies were used to enhance the substrate specificity towards glycerol. Directed evolution by error-prone PCR led to an AldO double mutant with 1.5-fold improved activity for glycerol. Further improvement of activity was achieved by combination of mutations, leading to a quadruple mutant with 2.4-fold higher specific activity towards glycerol compared to the wild-type enzyme. In small-scale biotransformation concentrations up to 2.0 g•l-1 D-glyceric acid could be reached using whole cells. Investi¬gation of the effects of the introduced mutations led to a further identification of es¬sential amino acids with respect to enzyme functionality and structural stability. ARTICLE II: KINETIC RESOLUTION OF GLYCERALDEHYDE USING AN ALDEHYDE DEHYDROGENASE FROM DEINOCOCCUS GEOTHERMALIS DSM 11300 COMBINED WITH ELECTROCHEMICAL COFACTOR RECYCLING. WULF, H., PERZBORN, M., SIEVERS, G., SCHOLZ, F. & BORNSCHEUER, U. T. (2012). J. Mol. Catal. B Enzym. 74, 144-150. Two aldehyde dehydrogenases (ALDH) from Escherichia coli BL21 and Deinococcus geother-malis were cloned, characterized and evaluated according to their applicability for a bio-catalysis setup with electrolytic cofactor recycling. Both ALDHs turned out to have a sim¬ilar substrate scope and favor short to medium chain aldehydes and both oxidize glyceralde¬hyde to D-glyceric acid. The ALDH variant of D. geothermalis shows higher specific activity towards glyceraldehyde and has an elevated optimum temperature compared to the BL21 enzyme. Due to the higher specific activity of the ALDH of D. geothermalis, this enzyme was used to conduct a kinetic resolution of glyceraldehyde with electrolytic NAD+ recycling at a glassy carbon foam electrode with ABTS as redox mediator yielding in 1.8 g•l-1 glyceric acid. ARTICLE III: PROTEIN ENGINEERING OF A THERMOSTABLE POLYOL DEHYDROGENASE. WULF, H.*, MALLIN, H.*, BORNSCHEUER U.T. (2012). Enzyme Microb. Technol. 51, 217-224 (*equally contributed). The new enzyme polyol dehydrogenase PDH-11300 from D. geothermalis was extensively characterized regarding its temperature optimum and thermostability. A peptide stretch responsible for substrate recognition from the PDH-11300 was substituted by this particular stretch of a homolog enzyme, the galactitol dehydrogenase from Rhodobacter sphaeroides (PDH-158), resulting in a chimeric enzyme (PDH-loop). The substrate scopes were deter-mined and basically the chimeric enzyme represented the average of both wild-type en-zymes. A rather unexpected finding was the notably increased T5060, by 7°C to 55.3°C, and an increased specific activity against cyclohexanol. Finally, the cofactor specificity was suc¬cess-fully altered from NADH to NADPH by an Asp55Asn mutation, which is located at the NAD+ binding cleft, without influencing the catalytic properties of the dehydrogenase. ARTICLE IV: A SELF-SUFFICIENT BAEYER-VILLIGER BIOCATALYSIS SYSTEM FOR THE SYNTHESIS OF Ɛ-CAPROLACTONE FROM CYCLOHEXANOL. MALLIN, H. *, WULF, H. *, BORNSCHEUER U.T. (2013). Enzyme Microb. Technol., online, DOI: 10.1016/j.enzmictec.2013.01.007 (*equally contributed). The application of the engineered PDH-loopN mutant [1] (Article III) for the production of ε-caprolactone from cyclohexanol was investigated in a co-immobilization approach with the cyclohexanone monooxygenase from Acinetobacter calcoaceticus. Biotransformation with solubilized enzymes led to an isolated yield of 55% pure ε-caprolactone with no residual cy-clohexanol to be detected. During the immobilization experiments a higher enzyme ratio in favor of the CHMO led to higher reaction velocities. Similarly, the addition of soluble fresh CHMO during reuse of co-immobilization batches significantly increased the activity identi-fying the CHMO as the bottleneck in this reaction setup.
The definition of Green Chemistry was first formulated at the beginning of the 1990s – 30 years ago and states as follows: “design of chemical products and processes to reduce or eliminate the use and generation of hazardous substances” (Poliakoff et al. 2002). Biocatalysis is one of the examples of “green” chemistry as it is relying on natural or modified enzymes. Today, biocatalysis is a standard technology for the production of chemicals (Straathof et al. 2002).
In this PhD thesis, the implications of biocatalysis using different class of enzymes are discussed: two cytochrome P450 monoxygenases, two kinases and one lyase are shown as tools for the production of bioactive compounds.
The P450 enzymes have a central role in the oxidative metabolism of a wide variety of compounds including the synthesis of endogenous substrates such as steroids and fatty acids. Moreover, P450s catalyze the hydroxylation of non-activated carbon atoms in a regio- and stereospecific fashion avoiding use of protecting groups and several, time-consuming chemical steps.
Here, the recombinant expression and biocatalytic characterization of bacterial CYP107D1 for the regio- and stereoselective hydroxylation of two steroid compounds is reported. Since the natural electron transfer partners of these P450s are unknown, PdX and PdR from P. putida were employed to supply CYP107D1 with the necessary electrons for catalysis. This three-component system was used in bioconversions of two bile acids: LCA and DCA. P450 CYP107D1 exhibits high regio- and stereoselectivity for the tested steroids, giving 6β-hydroxylated products. The properties of the CYP107D1 make this multifaceted P450 monooxygenase an attractive enzyme for the production of novel drug metabolites. Moreover, the crystal structure of the enzyme is known, which provides the basis for developing a protein-engineering strategy aimed at catalytic properties of the CYP107D1
The second enzyme described in the thesis is the self-sufficient cytochrome P450 monooxygenase from Fusarium graminarium (FG067). From the overall structure, it resembles the well investigated CYP102 from Bacillus megaterium (CYP BM3) and the P450 from Fusarium oxysporum (CYPfoxy). In this study, two different strategies to recombinantly produce the fungal P450 monooxygenase P450-FG067, namely (a) producing in E. coli and (b) producing in P. pastoris were investigated. The P450 FG_067 from Fusarium graminarium was successfully overexpressed in P. pastoris. The enzyme was functionally active, converted fatty acid substrates of carbon chain length C10-16 with regiospecificity of the hydroxylating position ω -1, ω - 2 and ω-3, with the highest affinity for capric acid. The hydroxylation at different positions of the fatty acid chain is needed for different chemical industries. For example, ω-HFAs can be used as starting materials for the synthesis of polymers, with high resistance to heat or chemicals (Xiao et al. 2018). Therefore, the application of recombinant enzyme such as self-sufficient P450 FG_067 for a commercial production of HFAs is in high industrial demand.
In this thesis, two kinases were used for the producton of phosphorylated metabolites. Kinases catalyzing N-phosphorylation, which are of synthetic interest because of tedious chemical procedures in selective chemical N-phosphorylations. A highly active and stabile arginine kinase, obtained by cloning and expressing the argK gene from Limulus polyphemus in E. coli, was used in the one-step synthesis of Nω-phospho-L-arginine using the phosphoenolpyruvate/pyruvate kinase system for ATP regeneration. Applying arginine kinase in biocatalysis opens up new opportunities for the selective biocatalytic N-phosphorylation of interesting low-molecular-weight compounds and metabolites.
Another kinase investigated in this thesis was shikimate kinase. The highly active and stable shikimate kinase AroL was achieved by synthesizing the codon-optimized aroL gene and expressing it in high yield in E. coli. Next, shikimate kinase was used in an one-step synthesis of shikimate-3-phosphate using the phosphoenolpyruvate/pyruvate kinase system for ATP regeneration. Development of the described biocatalytic preparation of shikimate-3-phosphate is a superior route incomparison to a tedious multi-step and low yield classical synthesis of this compound. The biocatalytic phosphorylation is of great interest for a commercial production of metabolites and metabolite-like structures.
The last investigeted enzyme in this PhD thesis was argininosuccinate lyase from Saccharomyces cerevisiae. The argininosuccinate lyase was cloned and overexpressed in E. coli as a highly active and stable biocatalyst. A simple and straightforward biocatalytic asymmetric Michael addition reaction has been established for the synthesis of the key metabolite N-(([(4S)-4-amino-4-carboxybutyl]amino)imino methyl)-L-aspartic acid, commonly referred to as L-argininosuccinate. This one-step addition reaction was developed by running part of the urea cycle in reverse. The use of this argininosuccinate lyase and reaction monitoring by NMR enabled the development of a biocatalytic asymmetric Michael addition reaction as a novel green chemistry route with high molecular economy for the synthesis of this important metabolite at gram scale.
Recent advances in the field of scientific research have helped to understand the structure and functional activities of enzymes, which has in turn led to an increase in their stability, activity and substrate specificity. Nowadays, biocatalysis provide more sustainable, efficient, and less polluting methods for the production of fine chemicals and advanced pharmaceutical intermediates. The biocatalysts used in this thesis are introduced as a technology for the efficient synthesis of biologically active compounds, which is greener, reduces pollution and costs compared to chemical synthesis. In summary, the pharmaceutical industry should use the advantage of the progress of biochemistry to obtain biocatalysts in the production of fine chemicals on an industrial scale, improving the quality of end products and saving costs.
Myxomycetes or Myxogastria (supergroup Amoebozoa) are one of several Protistean groups dispersing via airborne spores. The model organism for the group, so far exclusively studied in a laboratory environment, is Physarum polycephalum. Here, molecular evolution, distribution and the ecology of spores dispersal was investigated for the non-model species Physarum albescens. This nivicolous myxomycete fruits with snow melt in most mountain ranges of the northern hemisphere and disperses via spherical, dark-colored and melanin-rich spores. Fruit body development and subsequent spore dispersal occurs within a short time window of a few days. At this time, the fruiting plasmodium is fully exposed to the harsh environment if the protecting snow melts away. The spores, with a diameter of 10–13 µm of the typical size for myxomycetes, can potentially reach all suitable habitats worldwide, which led to the assumption that not only Ph. albescens but most myxomycete species should be ubiquitously distributed over the world.
In the first part of this study (article 1), the question was, if spore dispersal can realize a gene flow sufficient to meet the above-mentioned assumption. A total of 324 accessions of Ph. albescens, collected all over the northern hemisphere, was sequenced for 1-3 genetic markers (SSU, EF1A, COI), and 98 specimens were further analyzed using the genotyping by sequencing technique. As a result, at least 18 reproductively isolated units, which can be seen as cryptic biological species, emerged as phylogroups in a three-gene phylogeny, but as well in a SNP-based phylogeny and were confirmed by a recombination analysis between the three markers. However, this evolutive radiation is not simply caused by geographic fragmentation due to low dispersal capability: within a certain region, multiple phylogroups coexisted next to each other, although some appeared to be regional endemics. Most likely, mutations in mating-type genes, as shown to exist for the cultivable Ph. polycephalum, are the main drivers of speciation. This challenges the hypothesis of ubiquitous distribution of Ph. albescens and corroborates the results of the few available studies for other myxomycete species. In addition, groups of clonal specimens, mostly but not always restricted to a certain slope or valley indicated that sexual and asexual reproduction coexists in the natural populations of Ph. albescens.
In the second part (articles 2), the fundamental niche for Ph. albescens was described using all available records for the species. The resulting set of 537 unique occurrence points was subjected to a correlative spatial approach using the software MaxEnt. In dependence on the predictor variables three species distribution models emerged which differed only in details. The first consisted of only 19 bioclimatic variables and an elevation map from the WorldClim dataset. The second was corrected for pseudo-absences resulting from missing survey activities, and the third was expanded with an additional categorical environment variable on snow cover. High mean AUC (area under the curve) values above 0.97 could be reached with all three models. Variables for snow cover, precipitation of the coldest quarter (of the year), and elevation correlated highly to predict the distribution of Ph. albescens. Only in mid-northern latitudes, elevation alone was a good predictor, but it would cause false-positive predictions in arid mountain ranges and failed to explain occurrence in lowland sites at higher latitudes. Mountains in humid climates showed the highest incidences, confirming recent studies that long-lasting snow covers combined with mild summers are crucial for the ecological guild of nivicolous myxomycetes, with Ph. albescens as a typical species.
Spore size is crucial for dispersal ability and should thus be a character under strong selection. In addition, spores carrying two nuclei with opposite mating types should have a colonization advantage. This was the hypothesis for the last part of this study (articles 3 and 4), which investigated this trait in a quantitative manner. This required a method to analyze thousands of spores automatically (article 3) and with high precision for size and the number of nuclei enclosed. Human errors should be excluded, to reveal even subtle differences in the resulting spore size distributions. Two challenges had to be met for this approach. First, a preparation technique was developed to reduce false segmentations due to overlaying spores by aligning spores on one common plane with a high-frequency vibration device. Second, the segmentation process was automated to allow separating spores that are densely packed in the respective images. A machine learning algorithm was set up and trained to reliable identify and measure dark-colored spores. The technique produced consistent results with high accuracy, and the large number of spores allowed to compile spore size distributions, to check for the constancy of this character, which is impossible with manual measurements limited to low numbers.
The resulting spore size distributions, obtained from over 80 specimens (article 4), were mostly narrow, which is in accordance with our hypothesis. Spore size was as well fairly constant within fructifications from one colony. However, mean spore size within different accessions of Ph. albescens showed large variation (ca. 10%, a range often indicated to key out different morphospecies of myxomycetes), and this was explained only by a minor part with differences between biospecies. Not much smaller (8%) was the variation within a group of clonal specimens collected within 25 m distance. This points to a strong influence of environmental factors even at a micro spatial scale, perhaps caused by microclimatic differences and high phenotypic plasticity for spore size. The influence of large-scale covariates like altitude or latitude was negligible. However, spore size correlated with the variance in this trait, indicating that oversized spores may be caused by detrimental environmental conditions. Two aberrations in spore development were found: First, a few specimens showed a multimodal distribution for spore size with two or even three discernible spore populations. The estimated volumes of those populations correspond to a multiple of the first and most abundant conspicuous spore size population. Second, not all spores were uninucleate as to be expected for meiotic products. This was revealed by fluorescence signals from staining the same spores with DAPI, with a second machine learning algorithm trained to identify the nuclei in a spore. A few specimens showed a significant proportion of binucleated spores in the size range of normal-sized ones, and these specimens were not the ones with multimodal spore size distributions. This indicates that the negative impacts (inbreeding) of multinucleate spores should outweigh a possible colonization advantage and is in accordance with the high genetic diversity found in the worldwide population of Ph. albescens, indicating predominantly sexual reproduction in wild populations of myxomycetes.
Despite a plethora of therapeutic approaches, the injection of local anaesthetics itself remains one of the most painful and dreadful procedures among children. Stimulation of acupoint LI4 is associated with analgesic effects in dentistry. Goal of the study To investigate whether stimulation of LI4, added to standard therapy (ST), reduces pain and distress during injection of local anaesthetic (LA) in comparison with ST alone. Materials and Methods Children, scheduled for dental treatment in local anaesthesia on 2 separate days were enrolled in this trial, approved by local ethics commission. On one day each child received bilateral acupuncture of LI4 point, using indwelling fixed “New Pyonex” needles (0.2 x 1.5 mm; Seirin, Japan). The parents of the children were asked to stimulate the needles by massage. Standardized injection of LA was performed 5 min following acupuncture. The needles were withdrawn at the end of dental treatment. On the other day of treatment children received LA injection without acupuncture. The order of treatment days (acupuncture first or vice versa) was randomised. Primary endpoint was the pain intensity during LA injection reported by children on Visual Rating Scale from 0=no pain to 10=maximal pain imaginable (VRS-11). Secondary endpoints were parent- and dentist-assessed pain intensity (measured on Numeric Rating Scale 1-10), patients’ heart rate before and during dental treatment and satisfaction with received therapy (measured on Numerical Rating Scale 1-5.) Side effects of LI4 stimulation were also recorded. Results and Discussion The data of 49 children (22 females; age 10 ± 4 yrs; mean ± SD), who completed both visits, were analysed. Children reported less pain with than without acupuncture: 2.2 ± 2.5 vs. 3.9 ± 2.7; mean ± SD, p<0.001. Heart rate decreased after LI4 stimulation compared to ST alone throughout the dental treatment (p<0.05). LI4 stimulation was safe and raised better satisfaction with the treatment among children and parents, than ST alone (p<0.05). Other secondary endpoints were comparable between both sessions. Conclusion Stimulation of acupuncture point LI4 reduces pain and autonomous stress during injection of local anaesthetics in paediatric dentistry.
The introduction of two-dimensional polyacrylamide gel electrophoresis (2-D PAGE) enabled the separation and visualization of a substantial fraction of an organism’s entire proteome, and when mass spectrometry entered protein science, these proteins became even amenable to identification on a grand scale. Nevertheless, important classes of proteins elude a separation on classical 2 D gels, as the ones showing extremes in isoelectric point or molecular weight, and foremost very hydrophobic proteins naturally embedded in lipid membranes. This thesis aimed at the establishment and adaptation of alternatives to 2-D PAGE. New techniques allowing for an identification and quantification of critical protein classes were designed and adopted to physiological questions in the Gram-positive bacteria Bacillus subtilis and Staphylococcus aureus. In a comprehensive study on cytoplasmic proteins of S. aureus COL the number of proteins identified by a 2-D gel based approach could be extended by 650 proteins employing gel free technologies. Application of these complementary methods resulted in the establishment of a comprehensive reference map of the cytosolic proteome in growing and non-growing S. aureus cells which can serve as basis for further physiological investigations. Gel free separation of complex protein digests was likewise used in a quantitative study on heat stress in B. subtilis. By implementation of the iTRAQ® technology four different physiological states could be relatively quantified in one experiment. A parallel generation of 2-D gel based data enabled the depiction of strengths and weaknesses of protein quantitation by both, spot intensities on 2-D gels and iTRAQ® signal intensities in MS/MS spectra. Furthermore, new insights into heat sensitivity of pivotal enzymes involved in amino acid biosynthesis could be delivered. The institution of gel free approaches and advancements in 2-D PAGE provide the tools to penetrate into yet unamenable scopes of proteomes. A review on proteome coverage in B. subtilis gives an overview on the strategies which have been explored for most comprehensive protein identification in various sub-proteomes. Although more than one third of B. subtilis’ open reading frames could be demonstrated on protein level, one has to be aware of the fact that it still is a long way to achieve complete coverage of its proteome. Integral membrane proteins make up about one quarter of the entirety of proteins in a cell. Despite their large portion they are clearly understudied due to the intricacy of identification. Their low abundance and non-accessibility of membrane-spanning domains represent major experimental difficulties. The establishment of a protocol efficiently depleting cytosolic proteins by membrane shaving and targeting trans-membrane peptides by novel digestion strategies essentially facilitated identification of highly hydrophobic integral membrane proteins. This protocol was not only successfully applied to the membrane proteome of growing S. aureus cells, but was shown to be applicable in B. subtilis as well. Both studies displayed the novel membrane shaving approach to be highly complementary to a previously established separation of membrane proteins via 1 D PAGE. A combination of the two techniques resulted in identification of about half of the theoretical membrane proteome in both bacteria, and hence layed the foundation for advanced and quantitative analyses. In this regard, 14N/15N metabolically labeled membrane samples of growing and non-growing cells of S. aureus COL were relatively quantified revealing a significant difference in amount for more than one third of the proteins. A corresponding experimental setup was used to compare the membrane proteomes of S. aureus SA113 and its mutant deficient in the lysylphosphatidylglycerol synthetase MprF. Interesting quantitative differences were obtained for proteins most likely involved in the regulation of cellular surface net charge as well as for virulence-associated proteins.
Pentathiepins are cyclic polysulfides that exert antiproliferative and cytotoxic activity in cancer cells, induce oxidative stress and apoptosis, and potently inhibit GPx1. These properties render this class of compounds promising candidates for the development of anticancer drugs. However, the biological effects and how they intertwine to promote high cytotoxicity have not been systematically assessed throughout a panel of cancer cell lines from distinct tissues of origin. In this thesis, six novel pentathiepins were analyzed and constitute the second generation of compounds with additional properties such as fluorescence or improved water solubility to facilitate cellular testing. All compounds underwent extensive biological evaluation in 14 human cancer cell lines. These studies included investigations of the inhibitory potential with regards to GPx1 and cell proliferation, examined the cytotoxicity in human cancer cell lines, as well as the induction of oxidative stress and DNA strand breaks. Furthermore, selected hallmarks of apoptosis, ferroptosis, and autophagy were studied. Experimental approaches regarding these cellular mechanisms included observing morphological changes, detecting phosphatidyl serine exposure and caspase activity, and quantifying cleaved PARP1 and levels of LC3B II. In addition, the analysis of the cell cycle aimed to identify aberrations or arrests in cell division.
Five of the six tested pentathiepins proved to be potent inhibitors of the GPx1, while all six exerted high cytotoxic and antiproliferative activity, although to different extents. There was a clear connection observed between the potential to provoke oxidative stress and damage to DNA in the form of single- and double-strand breaks both extra- and intracellularly. Furthermore, various experiments supported apoptosis but not ferroptosis as the mechanism of cell death in four different cell lines. In particular, the externalization of PS, the detection of activated caspases, and the cleavage of PARP1 corroborated this conclusion. Additionally, indications for autophagy were found, but more investigations are required to verify the current data. The findings of this dissertation are mainly in line with the postulated mechanism of action proposed for pentathiepins and a previous publication from our group that described their biological activity. However, the influence of modulators such as oxygen and GSH on the biological effects was ambiguous and dependent on the compound. The expression profile of the cell lines concerning GPx1 and CAT did not influence the cellular response toward the treatment, whereas the cell doubling time correlated with the cytotoxicity.
As the various pentathiepins give rise to different biological responses, modulation of the biological effects depends on the distinct chemical structures fused to the sulfur ring. This may allow for future optimization of the anticancer activity of pentathiepins. An analysis of the structure-activity relationships revealed that the piperazine scaffold was associated with superior biological activity compared to the pyrrolo-pyrazine backbone. Furthermore, substituents with electron-withdrawing properties or those providing a free electron pair, such as fluorine or morpholine, were advantageous. These findings should help design and synthesize the next generation of pentathiepins, thereby expanding the library of compounds, allowing for the further deduction of structure-activity relationships and an improved understanding of their mechanism of action.
The genus Capripoxvirus of the family Poxviridae consists of the species lumpy skin disease virus, sheeppox virus and goatpox virus that affect cattle, sheep and goats, respectively. Whereas lumpy skin disease virus (LSDV) is transmitted mainly mechanically via blood-feeding insects and possibly hard ticks, the major transmission routes of sheeppox virus (SPPV) and goatpox virus (GTPV) are via direct contact and aerosols. Affected animals develop fever and display clinical signs such as ocular and nasal discharge, lymphadenopathy and characteristic lesions of the skin. Severe clinical course, especially in combination with respiratory signs, can result in the death of the affected animals. In endemic regions, mortality of capripox virus-induced diseases is low (1-10%). However, mortalities of up to 75% have been reported for LSDV and up to 100% for SPPV and GTPV in exotic breeds and high-producing dairy or beef animals. The loss of quality of the leather, reduced weight gain and milk yield as well as complete loss of affected animals have severe impact on national and global economies. Therefore, capripox virus-induced diseases have significant impact on both the affected individual animal as well as on the existence of small-scale farmers and large agricultural enterprises. However, until now, only live attenuated vaccines are commercially available. These attenuated vaccines are not authorized in the European Union and their administration would comprise the disease-free status of the respective country. Thus, reliable diagnostic tools for the detection and characterization of capripox viruses as well as safe and efficient control measures are of high importance.
The objectives of the present thesis were the development, validation and comparison of diagnostic tools, the establishment of challenge infection models and the performance of pathogenesis studies for all three capripox virus species, and the development and testing of different inactivated prototype vaccine candidates against LSDV.
First, new real-time quantitative polymerase chain reaction (qPCR) assays for robust detection and differentiation of LSDV field strains, LSDV vaccine strains, SPPV and GTPV were developed and extensively validated. In the following, two single assays were combined to duplex assays, one for the differentiation between LSDV field strains and LSDV vaccine strains, and the second for discrimination of SPPV and GTPV. Finally, a diagnostic workflow based on these new duplex assays in combination with already published methods was established. This workflow enables time-saving, robust and reliable detection, species-specific identification and genetic and phylogenetic characterization of all three capripox virus species. In addition, already existing serological examination methods (serum neutralization assay and commercial enzyme-linked immunosorbent assay) were compared regarding their sensitivity and specificity. Furthermore, pathogenesis studies with different capripox virus isolates were performed in the respective target species, and the suitability of selected virus isolates as challenge viruses for future vaccine studies was analyzed. Pathogenesis studies with isolates GTPV-“V/103” and LSDV-“Macedonia2016” revealed that both are proper candidates for challenge models. Finally, three different SPPV isolates (SPPV-“V/104”, SPPV-“India/2013/Surankote” and SPPV-“Egypt/2018”) were tested in sheep regarding their virulence to find a suitable challenge model for SPPV, and SPPV-“India/2013/Surankote” was chosen for future vaccine studies.
Once appropriate challenge models were established, different inactivated prototype vaccines against LSDV were developed, and vaccine safety as well as vaccine efficacy were tested in cattle. Eventually, a Polygen-adjuvanted inactivated LSDV-vaccine candidate was selected that is able to fully prevent cattle from any LSDV-related clinical signs after severe challenge infection. Furthermore, molecular and serological data indicate that this inactivated prototype vaccine is even able to induce a kind of “sterile immunity” against LSDV in those cattle. It has to be mentioned that a commercially available vaccine similar to this prototype vaccine would be a great advance for the control of LSDV.
In the future, additional studies addressing diagnostics and optimized control of capripox viruses should be performed. Firstly, probe-based real-time qPCR assays for the differentiation of SPPV and GTPV vaccine strains from their respective virulent field strains should be developed and included into the diagnostic workflow. Secondly, further tests of the inactivated prototype vaccine, e.g. determination of the minimum protective dose and the possibility of cross-protection in sheep and goats against SPPV and GTPV, respectively, should be performed.
This thesis describes the implementation and first on-line application of a multi-reflection time-of-flight (MR-ToF) mass analyzer for high-resolution mass separation at the ISOLTRAP mass spectrometer at ISOLDE/CERN. On the one hand, the major objective was to improve ISOLTRAPs mass-measurement capabilities with respect to the ratio of delivered contaminating ions to ions of interest. On the other hand, the time necessary to purify wanted from unwanted species should be reduced as much as possible to enable access to even more exotic nuclei. The device has been set up, optimized and tested at the University of Greifswald before its move to ISOLTRAP. The achieved performance comprises mass resolving powers of up to 200000 reached at observation times of 30ms and a contamination suppression of about four orders of magnitude by use of a Bradbury-Nielsen gate. With the characteristics, it outperforms clearly the so far state-of-the-art purification method of a gas-filled Penning trap. To improve the utilization of the MR-ToF mass analyzer, the in-trap lift method has been developed. It simplifies the application and optimization of the device, which is a crucial time factor in an on-line experiment. The device was the first of its kind successfully applied to radioactive ion beams for a mass analysis, for a mass separation (in combination with the Bradbury-Nielsen gate) as a preparatory step for a subsequent Penning-trap mass measurement and as a high-precision mass spectrometer of its own. The later was recently used for the first mass measurement of the neutron-rich calcium isotopes 53Ca and 54Ca. The so-far achieved mass-resolving power of 200000 belongs to the highest reported for time-of-flight mass analyzers at all. The first successful application of the MR-ToF system as the only mass separator at ISOLTRAP resulted in the mass measurement of 82Zn. The new mass value has been compared to mass extrapolations of the most recent Hartree-Fock-Bogoliubov (HFB) mass models, HFB-19 to HFB-21, of the BRUSLIB collaboration. The mass of the nuclide is of high interest for the compositions and depth profile of the outer crust of neutron stars. In the classical model of the outer crust of a cold, non-accrediting and non-rotating neutron star, the sequence of nuclides found within this parts is determined mainly by the binding energy of exotic nuclides. The crustal compositions determined with the three HFB mass models differed with respect to the appearance of a layer of 82Zn, originating from different mass extrapolations of this mass. With the new experimental data, the extrapolations could be evaluated. It was found that the HFB-21 mass value differs less from the experimental data than the ones from HFB-19 and 20. Therefore, in the classical model, 82Zn does not appear anymore in the outer crust. Due to its high resolution and very fast measurement time, the MR-ToF mass analyzer will be an important instruments for future activities at ISOLTRAP, at the ISOLDE facility in general, and at other radioactive ion-beam facilities.
Plasma medical oncology: Immunological interpretation in head and neck squamous cell carcinoma
(2020)
Over the past several years, various important articles focusing on cancer therapy
approaches in head and neck squamous cell carcinomas (HNSCCs) using cold
atmospheric plasma (CAP) have been published (SEMMLER et al. 2020 [53],
METELMANN et al. 2018 [44], KEIDAR et al. 2011 [33]). This doctoral thesis presents
selected results from a prospective observational clinical study in CAP therapy of
palliative HNSCC patients, carried out at the Department of Oral and Maxillofacial
Surgery/Plastic Surgery of the Greifswald University Medicine. For oral and
maxillofacial surgeons, ulcerated surfaces of locally advanced head and neck squamous
cell carcinomas (UICC IV) offer a challenging treatment assignment with microbial
contamination and tumour progression. The clinical attempt appears to eradicate
microbial contamination and to initiate tumour regression. This doctoral thesis will
describe the processes of human tumour biology and tumour immunology in HNSCCs
and the extent of present knowledge concerning plasma medical oncology as an
anticancer modality. In the introduction of the doctoral thesis clinical results of plasma
therapy in locally advanced HNSCCs (UICC IV) are set out. This mainly includes the
investigation of a therapeutic concept, the treatment phases, the tumour size development
and the morphological changes of the infected tumour surface following cold atmospheric
plasma therapy. In the main part, a detailed immunological interpretation is proposed on
the basis of present preclinical and clinical immunological knowledge. Finally,
unexplored questions in plasma medical oncology are highlighted. This is highly
significant for future plasma research and clinical anticancer therapy.
The study of sow reproduction traits is important in livestock science and production to increase animal survival and economic efficiency. This work deals with the detection of different effects on within-litter variance of birth weight by applying different statistical models with different distributional assumptions. The piglets within one litter were separated by sex. The trait of sow was formed from the sample variances of birth weights within litter separated by sex to consider the sex effect on mean birth weight. A linear mixed model (LMM) approach was fitted to the logarithmized sample variance and the sample standard deviation. A generalized linear mixed model with gamma distributed residuals and log-link function was applied to the untransformed sample variance. Appropriate weights were constructed to account for individual litter sizes. Models were compared by analysing data from Landrace and Large White. The estimates of heritability for the different traits ranged from 6-14%. The LMM for the weighted standard deviation of birth weights was identified as most suitable in terms of residual normality. Furthermore, the impact of piglets´ sex on birth weight variability was tested, but it was only proved for one practical dataset. Additionally, we analysed the influence of including or not including birth weights of stillborn piglets on the estimates of variance components of birth weight variability. With omitted stillborns the estimates of heritability resulted in about 2% higher values than in investigations of total born piglets. We were interested in the presence of the random boar effect on birth weight variability. The corresponding variance component was tested via restricted likelihood ratio test. Among others, the null distribution of the test statistic was approximated by parametric bootstrap simulations which were computational intensive. We picked up a two-parametric approach from literature and proposed a three-parametric approach to approximate the null distribution of the test statistic. We have analysed correlated data in balanced (simulated data) and unbalanced (empirical data) designs. The two-parametric approach using a scaled mixture of chisquare-distributions as well as a three-parametric approach, that uses a mixture of the point mass at zero and a gamma distribution, behaved most solid in all investigations and were most powerful in the simulation study.
Cardiovascular diseases are the most common cause of death in industrial nations. The basis of these diseases is a dysfunction in the interaction between the cells the heart is composed of. The main types of cells making up the human heart are cardiomyocytes that build the myocardium and provide the contraction properties, endothelial cells that delimit the blood flowing through the inner chambers and coronary arteries from the myocardial tissue, and fibroblasts, which build the connective tissue. A common process in the development of cardiovascular diseases is the formation of fibrosis due to injury of the endothelium and subsequent infiltration of the cardiac tissue by immune cells, and inflammatory agents like cytokines. Cytokines exert different functions in cardiac cells. Tumor necrosis factor α (TNFα) is an inducer of apoptosis. Transforming growth factor ß (TGFß) is known for activation of proliferation. Other cytokines like C-X-C motif chemokine 11 (CXCL11), interleukin-6 (IL-6), or brain-derived neurotrophic factor (BDNF) have not yet been investigated or their impact on such cells is unknown. Eventually, however, fibrotic scar tissue arises from the transition from fibroblasts to myofibroblasts leading to a stiffening of the cardiac muscle and impaired pump function. In order to prevent the occurrence of these events the balance of proliferation, migration, and differentiation of cardiac cells needs to be controlled very delicately.
The mechanisms controlling these interactions are still not well understood, which is why this work aimed at the elucidation of molecular mechanisms within the three main cell types that might play a role in the regulation of cardiac function. A proteomic approach using mass spectrometry was used to identify alterations in protein levels that could provide hints about the involved pathways and find new players as candidates for more detailed investigation. Initially, the proteomic composition of HL-1 cardiomyocytes, L929 fibroblasts, and human umbilical vein endothelial cells (HUVECs) that were cultivated in standard growth conditions without stress was investigated. Half of the total protein intensity was made up by only 42 to 53 proteins, depending on the cell type. More than a third of all proteins were identified in all three cell types, which may be proteins performing common cell functions. Indeed, the proteins displaying the highest abundance seem to be predominantly involved in such common cellular functions as the regulation of glucose metabolism or the cytoskeleton. More specific functions like heart development and muscle contraction were found enriched in cardiomyocytes as were mitochondrial proteins. The proportion of proteins with extracellular localization and function was higher in fibroblasts and endothelial cells.
Secondly, the impact of cytokines on the proliferative behavior and the proteomic composition of cardiomyocytes and fibroblasts was analyzed. HL-1 cardiomyocytes and L929 fibroblasts were treated with different concentrations of cytokines with a cytotoxic, proliferative, or yet unknown effect on these cells. While HL-1 cells exhibited no macroscopic reaction to any of the cytokines used, cytotoxic/growth inhibitory (TNFα, CXCL11) and proliferative (TGFß, IL6, BDNF) effects were observed for L929 cells. The latter also showed CXCL11-induced upregulated EIF2 signaling, pointing to a higher need of protein synthesis.
The third aim was the examination of proteome adaptations in endothelial cells due to different kinds of stress, as these cells are the first line of defense against inflammatory agents or injury and therefore prone to wounding. The role of the growth factors vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) in wounding and starvation was another object of this study as they are known for their angiogenic and cell survival supporting properties. Additionally, the impact of the cellular sex on the response to stress and growth factors was examined, because a person’s sex plays an important role in susceptibility, risk factors, and outcome of cardiovascular diseases. This has mainly been attributed to the different hormone levels, especially the higher levels of estrogen in premenopausal women, which exerts cardioprotective properties, but also genetic background was reported to play an important role. Only few studies that examined the molecular properties of HUVECs considered the cellular sex and if so, the genetic bias of unrelated samples was not taken into account. This is why Lorenz and colleagues at the Charité in Berlin collected HUVECs from newborn twins of opposite sex, cultivated them without stress in standard growth medium, exposed them to wounding and serum starvation, and investigated the impact of the growth factors and the sex on migrational behavior and metabolic issues. The current work focused on the alterations of not only the intra- but also the extracellular proteome, because paracrine signaling is crucial for intercellular communication in order to cope with stress. General differences between male and female cells were observed for proteins encoded on the X chromosome with higher levels in females (DDX3X, UBA1, EIF1AX, RPS4X, HDHD1), except for one protein with higher levels in male cells (G6PD). A Y-chromosomal protein was, for the first time, identified in endothelial cells (DDX3Y). Wounding, starvation, and growth factor treatment led to alterations and sex-specific different levels in an unexpectedly high number of proteins, with VEGF showing a stronger impact than bFGF. Many proteins with alterations observed without taking the sex into account, were actually only changed in male or female cells. Some proteins were regulated in opposite directions, or growth factors inhibited their secretion in a sex-specific way by unknown mechanisms. Tissue factor pathway inhibitor 2 (TFPI2) should be emphasized as a protein with sex-specific differences, especially in the extracellular space and with increased levels after starvation and VEGF treatment. These observations suggest a temporal lack in TFPI2 synthesis and secretion in male cells, which might explain the enhanced adaptation of females to wounding.
The results of this work lay the basis for future investigation by providing a database of intra- and extracellular proteome changes due to different environmental circumstances. It strongly suggests the investigation of male and female HUVECs, and other cells, separately to avoid the impact of the sex observed in this work. Essentially, the observations suggest a number of candidate proteins for more detailed investigations of endothelial and cardiovascular diseases.
The Effect of the Patients Nutritional Status on Immune Alterations Induced by Ischemic Stroke
(2018)
Ischemic stroke is one of the leading causes of death and disability throughout the world.
One important aspect of stroke pathophysiology are immunological changes after stroke, especially a combination of post stroke immunodepression, leading to
infectious complications after stroke and an activation of the immune system, leading to cerebral injury. Adipose tissue has several immunological functions and obesity
leads to immunological complications and is accompanied by a chronic immune activation.
To study the effects of body weight and obesity on the immune system and measure weight and fat tissue changes after ischemic stroke we conducted the LIPS Trial and enrolled 50 stroke patients and 16 control subjects between July 2015 and July 2016. On the day of admission and on the days 1, 2, 3, 4, 5, 7, 30, 90 and 180 after admission stroke patients were weighed with an in-bed scale, body composition was measured with BIA, the triceps-skin fold thickness was measured, the NIHSS scale was obtained and blood was drawn. FACS-analysis was performed and triglycerides,cholesterol, CRP and PCT were measured at the central laboratory facility of the Universitätsmedizin Greifswald. Luminex-multiplex analysis for multiple cyto- and chemokines was performed at the Multiplex Facility at the University Leiden. A cerebral MRI and an abdominal MRI were performed shortly after admission and on days 5-7 for most patients and the infarct volume, abdominal fat and hepatic fat percentage were measured. On days 30, 90 and 180 after stroke Bartel Index and mRS were obtained.
After stroke our patients showed the typical immunological changes described previously as stroke induced immune alterations, namely a post stroke immunodepression as well as signs of an activated immune system and an acute
phase response. Our patients lost weight, but only 1.7 ± 0.5 kg. Skinfold thickness did not change during the course of our trial and abdominal fat measurement did not change in stroke patients. Immunological parameters (leukocytes, neutrophils,CRP, PCT, IL-6) did not differ between BMI subgroups (normal weight: BMI < 25,overweight: BMI ≥ 25, < 30, obese: BMI ≥ 30) and in this trial we could not detect a
difference in patients with normal weight, overweight or obesity in the post stroke periode. In an additional analysis we could show that rapid clinical improvement
did result in a rapid improvement of post stroke immune alterations, especially for leukocytes, neutrophils, IL-6 and CRP.
The study of host-pathogen interactions is central to a better understanding of the human microbiome, infections and the inner workings of immune cells. One focal point of this research is how the human immune system recognises both harmful and harmless antigens, integrates the resulting signals and forms a response, and how, conversely, microbes can manipulate this reaction.
In this thesis, Pseudomonas aeruginosa (P. aeruginosa), a critical pathogen in chronic and nosocomial infections, was in the focus. The aim was to search for bacterial proteins that favour a type 2 immune response, as it is orchestrated by CD4+ type 2 T helper cells (Th2 cells). The humoral arm of a type 2 response is dominated by IgG4 and IgE. Such immune responses are typically directed against multicellular pathogens like helminths and other parasites. However, type 2 immune responses are suboptimal for the defence against extracellular bacteria like P. aeruginosa. Previous research suggests that some bacterial proteins may promote a switch to such an insufficient immune response as a mechanism of immune evasion.
To optimise the sensitivity of the search for type 2 response inducing proteins of P. aeruginosa, cystic fibrosis (CF) patients were studied, as many are exposed to the pathogen in their airways over prolonged time periods. As such, the humoral immune response of 9 CF patients to their own P. aeruginosa strain was examined. For this, the secretomes of 9 clinical P. aeruginosa isolates from CF patients and the P. aeruginosa reference strain PAO-1 were studied by 2D-immunoblotting for their ability to be bound by IgG4 and IgG1 from respective patient sera. IgG4 served as a proxy for IgE, as assays analysing IgE binding suffer from low sensitivity because of low serum concentrations of IgE. Antibody reactive P. aeruginosa proteins were then identified by liquid chromatography tandem mass spectrometry and the results were compared with proteomics data from literature.
In total, 308 distinct protein spots were analysed. These belonged to 17 bacterial proteins, which comprise the entire known P. aeruginosa secretome. Of these spots, 232 were bound by IgG4, and 24 by IgG1 only. Notably proteases like serralysin and P. aeruginosa elastase presented with an IgG4 bias. This is concordant with previous research linking proteases to a type 2 immune response. Moreover, structural proteins like
agellins were also immunodominant. Flagellins are known as common targets of immune detection in bacteria. These proteins also demonstrated a clear IgG4 bias.
Thus, the search for secreted P. aeruginosa proteins that elicit an IgG4-dominated antibody response was successful. It remains to be shown whether these bacterial proteins are also recognized by IgE and Th2 cells, meaning whether they are truly driving a type 2 immune response in CF patients. It is also an open question whether the observed IgG4 bias in the antibody response to the exoproteome of P. aeruginosa is specific to CF or a general feature of the human immune response to the pathogen.
There is multiple evidence that emotionally arousing events are preferentially processed, and better remembered than neutral events. In the present dissertation I investigated whether those strong emotional memories are affected by acute and chronic stress. Moreover, I was interested in whether already established emotional memories can be changed by behavioral intervention. According to the modulation hypothesis, emotionally arousing events promote attention and memory processes via noradrenergic and glucocorticoid actions. Recent models suggest that stress hormones differentially impact mnemonic processing, namely encoding, (re-) consolidation and memory retrieval, depending on timing and duration of the stressor relative to the learning experience. Acute stress around the time of encoding has been found to enhance memory, whereas chronic stress has been associated with memory impairments. Furthermore, consolidated memories are not resistant to modifications. Following reactivation, memories can turn into an unstable state and undergo a process called reconsolidated in order to persist. During this vulnerable state, memories are prone to modification, for instance by pharmacological blockade or interference learning. Here, the modulation of newly formed emotional and neutral memories as well as existing emotional and neutral memories was investigated in a well-established picture viewing and recognition memory paradigm using behavioral and neurophysiological measures (event-related potential, ERPs). More elaborative processing of emotional, relative to neutral stimuli has been related to the late positive potential (LPP). During encoding of emotional and neutral pictures, enhanced LPPs (starting at about 400 ms after stimulus onset) are usually observed for emotionally arousing relative to neutral pictures, indicating preferential attention allocation and processing. During recognition, correctly recognized old items evoke larger ERP amplitudes than correctly identified new items. This difference, the ERP old/new effect, was used to measure mnemonic processing during retrieval. The ERP old/new effect over centro-parietal sensor sites (400-800 ms) has been associated with recollection processes, and is enhanced for emotional, compared to neutral materials. Three studies are presented, that investigated 1) the influence of acute stress prior to encoding on long-term memory and its neural correlates, 2) the impact of chronic stress on encoding and memory, and 3) the influence of interference on already established memories (reconsolidation), always contrasting emotionally arousing and neutral scenes. Study 1 investigated subsequent recognition memory after encoding following acute stress using a socially evaluated cold pressure test, while study 2 tested the influence of chronic stress investigating breast cancer survivors about two years after cancer treatment. In study 3, one day after encoding, reconsolidation of the reactivated picture memory was targeted with an interfering learning task. In all three studies, recognition memory was tested one week later. High-density electroencephalograms (EEGs; 257 electrodes) were recorded to measure brain potentials. The results showed, in line with previous research, that emotionally arousing scenes were preferentially processed, as indicated by larger LPPs, and were better remembered than neutral scenes, as indicated by enhanced memory performance and larger ERP old/new differences. Experiencing acute stress prior to encoding enhanced the centro-parietal ERP old/new effect for emotionally arousing pictures at recognition, corroborating that acute stress facilitates memory for emotional scenes (Study 1). In contrast, attenuated LPPs for unpleasant pictures and impaired memory performance for arousing pictures were observed in breast cancer survivors (Study 2), indicating altered attention to emotion and subsequent emotional memory storage in chronically stressed individuals. When memory reactivation was followed by an interfering learning task, recognition memory and ERP old/new differences were attenuated for emotionally arousing scenes, selectively, showing the possibility that emotional memories might be modulated by behavioral interventions (Study 3). The results of all three studies are discussed and integrated into a model of memory modulation by stress and interference. The results highlight the importance of understanding the role of emotional arousal in the processes of memory formation, retrieval and reconsolidation. Moreover, shedding light on the differential effects of acute and chronic stress, interference and their possible interactions might help to prevent and even modify impairing memories that are one of the major concerns in stress- and fear-related mental disorders.
Unstable environments and habitats changing due to climate change force individuals to either respond by genetic adaptation, phenotypic plasticity or by dispersal to suitable environments. Theodoxus fluviatilis (Linneaus, 1758) is a good study organisms when researching phenotypic plasticity and genetic adaptation as it naturally appears in freshwater (FW) as well as brackish water (BW) and thus inhabits a wide range of environmental salinities (0-18‰). It is a euryhaline snail that can be found in shallow waters with stony ground or on Fucus spp. and has formed regional subgroups. The brackish water and the freshwater subgroups are spatially separated and the species cannot be found in areas inbetween, e.g. estuaries.
The species shows great variability in shell patterning and shell size and there is still debate whether the subgroups are distinguishable by these traits or not. The mitochdrial RNA marker cytochrome c subunit I did not show differences between the subgroups indicating that they must be closely related, but salinity tolerance has been observed to be higher in BW snails. This might be caused by the different protein expression patterns and osmolyte accumulation (measured as ninhydrin-positive substances) observed in this species in previous studies. The exact mechanisms regulating protein expression and osmolyte accumulation, however, are not fully understood yet.
Data collected for this thesis shows differences in shell size and suggests a less strict grouping of FW and BW individuals as shell sizes of one FW site are more similar to BW individuals than the other FW ones. A better salinity tolerance towards high salinities and a higher physiological salinity limit of BW snails was confirmed and extended by demonstrating an expanded tolerance range through slow acclimation to challenging salinities in snails from both subgroups. This was achieved by a shift in the slope of their reaction norms that was much more pronounced in BW snails than FW ones. S3 individuals showed a shift similar to that of BW individuals. The data for the salinity tolerance indicates that the underlying mechanism for these tolerances are a combination of phenotypic plasticity and genetic adaptation. Despite an acclimation and shift in the slope of the reaction norms and therefore an increased tolerance towards high salinities (plasticity) FW individuals from two collection sites were not able to cope with salinities as high as BW individuals (local adaptation). The general ability to mobilise free amino acids (FAA) as organic osmolytes was not the reason for this tolerance difference. Individuals from BW and FW sites were capable of accumulating quantities of FAAs equally well. Proline, alanine and urea were the most important components of the accumulated cocktail of organic osmolytes. Even though the total amount of FAAs accumulated under hyperosmotic conditions was the same in both subgroups, there were differences in the metabolic pathways involved in osmolyte accumulation in the foot muscle. The data indicates that the hydrolysis of storage proteins and the synthesis of proline and alanine are the main processes to avoid detrimental body volume shrinkage in T. fluviatilis. While FW individuals seemed to rely on the degradation of proteins and synthesis of alanine, BW individuals depended on newly synthesising proline and alanine and accumulating urea as a side product of transamination. The accumulation of urea is a new finding in aquatic living snails and has not been reported as a mechanism to avoid cell volume shrinkage in these animals.
Differing protein expression patterns were observed under control conditions across all collection sites. 9 spots showed volume changes in BW snails opposite to those of FW snails from collection sites S1 and S2. For 6 of those spots, S3 individuals showed patterns similar to those of BW individuals and for the remaining 3 they showed patterns similar to those of FW animals. The patterns observed when exposing snails to hypo- or hyperosmotic stress were not conclusive in relation to pinpointing individual spots that show the same pattern in all collection sites, but revealed the heterogeneity of protein expression in snails from the different collection sites and in the process of osmoregulation. It also showed the general tendency of protein reduction when snails where under osmotic stress of either kind (hypo- or hyperosmotic), which supports the hypothesis of storage protein degradation.
The investigation of an ANP-receptor showed two variations of the encoding sequence expressed in T. fluviatilis. S3 individuals as well as BW individuals were found to express one type, while FW individuals, with the exception of one sample expressed the other type. This showed that the FW subgroup of T. fluviatilis seems to be more heterogeneous than the BW subgroup, but also raises the question of the dispersal history of this species. The collected data indicates that T. fluviatilis individuals are firstly capable of surviving the acidity of a duck's gizzard and secondly can tolerate acute salinity changes to 16‰ when introduced into a new environment. Hence, if snails from the FW were to be transported to waters with a salinity of up to 16‰ by man, bird, drifting plants or some other means of transport, they would most likely survive and possibly be able to thrive and spread.
In the PhD-thesis a conditional random field approach and its implementation is presented to predict the interaction sites of protein homo- and heterodimers using the spatial structure of one protein partner from a complex. The method includes a substantially simple edge feature model. A novel node feature class is introduced that is called -change in free energy-. The Online Large-Margin algorithm is adapted in order to train the model parameters given a classified reference set of proteins. A significantly higher prediction accuracy is achieved by combining our new node feature class with the standard node feature class relative accessible surface area. The quality of the predictions is measured by computing the area under the receiver operating characteristic.
This thesis describes mass measurements at ISOLTRAP/ISOLDE/CERN in the region of the neutron-rich calcium isotopes. For the less exotic and more abundantly produced isotopes 51Ca and 52Ca the Penning trap based ToF-ICR technique could be used to validate the available mass data and to improve their precision. For the isotopes 53Ca and 54Ca, a Multi-Reflection Time-of-Flight Mass Spectrometer (MR-ToF MS) was used to determine the mass of these exotic isotopes for the first time experimentally. This also represents the first time an MR-ToF MS was applied to derive the masses of previously unknown radioactive ions from the high precision time-of-flight data that can be gathered with the device. The mass data was then used to benchmark the strength of the N=32 neutron subshell closure and at the same time to compare to state-of-the-art shell-model calculations.
Furthermore, the capability of the MR-ToF device to deliver isobarically pure beams to a subsequent experiment was developed further and studied in detail. The new technique is based on the in-trap lift, which is normally used to in- and eject ions into and from the device. With this new selective ejection technique after separation of the ion ensemble in the MR-ToF trap, no external components are required.
Additionally, a new stabilization system for voltages supplies, based on a PI-algorithm, was developed and thoroughly tested. The stabilized voltage supply was then used to supply the most sensitive mirror voltage of the MR-ToF MS to significantly increase the short term and long-term mass resolving power of the apparatus.
Mathematical phylogenetics provides the theoretical framework for the reconstruction and analysis of phylogenetic trees and networks. The underlying theory is based on various mathematical disciplines, ranging from graph theory to probability theory.
In this thesis, we take a mostly combinatorial and graph-theoretical position and study different problems concerning phylogenetic trees and networks.
We start by considering phylogenetic diversity indices that rank species for conservation. Two such indices for rooted trees are the Fair Proportion index and the Equal Splits index, and we analyze how different they can be from each other and under which circumstances they coincide. Moreover, we define and investigate analogues of these indices for unrooted trees.
Subsequently, we study the Shapley value of unrooted trees, another popular phylogenetic diversity index. We show that it may fail as a prioritization criterion in biodiversity conservation and is outcompeted by an existing greedy approach. Afterwards, we leave the biodiversity setting and consider the Shapley value as a tree reconstruction tool. Here, we show that non-isomorphic trees may have permutation-equivalent Shapley transformation matrices and identical Shapley values, implying that the Shapley value cannot reliably be employed in tree reconstruction.
In addition to phylogenetic diversity indices, another class of indices frequently discussed in mathematical phylogenetics, is the class of balance indices. In this thesis, we study one of the oldest and most popular of them, namely the Colless index for rooted binary trees. We focus on its extremal values and analyze both its maximum and minimum values as well as the trees that achieve them.
Having analyzed various questions regarding phylogenetic trees, we finally turn to phylogenetic networks. We focus on a certain class of phylogenetic networks, namely tree-based networks, and consider this class both in a rooted and in an unrooted setting.
First, we prove the existence of a rooted non-binary universal tree-based network with n leaves for all positive integers n, that is, we show that there exists a rooted non-binary tree-based network with $n$ leaves that has every non-binary phylogenetic tree on the same leaf set as a base tree.
Finally, we study unrooted tree-based networks and introduce a class of networks that are necessarily tree-based, namely edge-based networks. We show that edge-based networks are closely related to a family of graphs in classical graph theory, so-called generalized series-parallel graphs, and explore this relationship in full detail.
In summary, we add new insights into existing concepts in mathematical phylogenetics, answer open questions in the literature, and introduce new concepts and approaches. In doing so, we make a small but relevant contribution to current research in mathematical phylogenetics.
Drainage has commonly been a pre-requisite for the productive use of peatlands. The biased focus on agriculture, forestry and peat extraction has long ignored the destructive effects of drainage and the successive degradation of ecosystem functions of wet peatlands. Accelerated by the climate crisis, the finite nature of drainage-based peatland use is increasingly recognised. Consequently, productive land use options for wet or rewetted peatlands (paludiculture) are required as sustainable alternatives. A wide range of paludiculture plants and options of biomass utilisation are identified as suitable and promising. Despite the growing interest, experiences with and research on the economic viability of paludiculture are still rare.
This thesis addresses the lack of knowledge on paludiculture in terms of practical feasibility, costs and benefits at the farm level, market prospects and framework conditions. I selected the two currently most advanced paludicultural practices in Europe: a) Harvesting natural reed beds as a traditional ‘low-input’ paludiculture, i. e. the utilisation of existing ‘wild’ vegetation stands; b) ‘Sphagnum farming’ as a novel ‘high-input’ paludiculture including stand establishment and water management required for the active transformation from drainage-based peatland use to paludiculture. In both cases, I investigate three different biomass utilisation avenues. This thesis adds to the fields of problem-driven sustainability and land-use science. Procedures and costs of paludiculture were studied in transdisciplinary research projects in close cooperation with practitioners. Due to the novelty of the topic, I put special emphasis on the triangulation of methods and data sources: pilot trials, field measurements, semi-structured expert interviews, structured questionnaires, secondary data from trade statistics and literature. To account for uncertainty related to costs and revenues, I conduct stochastic scenario analysis (Monte Carlo simulation) for the extended contribution margin accounting of harvesting reeds and sensitivity analysis for the investment appraisal of Sphagnum farming.
Paludiculture on fens: harvesting reeds
Paper I investigates harvesting procedures for reed-dominated (Phragmites australis) vegetation stands. In many European countries special-purpose tracked machinery is applied for large-scale conservation management and the commercial harvest of thatching reed. Stochastic scenario analysis reveals a wide range of possible economic outcomes (ca. € -1000 to € 1500 ha-1 a-1) and identifies material use of reed superior to its use as a source of energy. Winter harvest of high-quality thatching reed in bundles is the most profitable option. Winter harvest of bales for direct combustion is suitable for low-quality stands and has a limited risk of loss. In the case of summer harvest, revenues for green chaff for biogas production cannot cover harvesting costs but non-market income via subsidies and agri-environmental payments may ensure profitability. While biomass for energy generation is limited to a local market, thatching reed is traded as an international commodity. The market situation for thatching reed is investigated for Europe (Paper II) and Germany (Paper III). The major reed consuming countries in Western Europe (Netherlands, Germany, UK, Denmark) rely on imports of up to 85 % of the national consumption, with reed being imported from Eastern and Southern Europe and since 2005 also from China. The total market volume for reed for thatching in Northern Germany is estimated with 3 ± 0.8 million bundles of reed with a monetary value at sales prices of € 11.6 ± 2.8 million. Most of the thatchers (70 %) did not promote reed of regional origin to their customers due to insufficient availability in the first place and a lack in quality as second reason. The cultivation of reed in paludiculture may improve quantity and quality of domestic thatching reed. An area of 6000 ± 1600 ha with an average yield of 500 bundles per hectare would allow covering the current total demand of 3 million bundles of the German thatching reed market (Paper III).
Paludiculture on bogs: Sphagnum farming
Sphagnum farming provides an alternative to peatland degradation in two ways: Firstly, Sphagnum mosses can be cultivated as new agricultural crops on rewetted peatlands. Secondly, the produced Sphagnum biomass is a high-quality raw material suitable to replace peat in horticultural growing media (Paper V). Pilot trials have demonstrated the practical feasibility of establishing Sphagnum cultures on former bog grassland, cut-over bogs and mats floating on acidic waters bodies; Paper IV compares for the three types of production sites the specific procedures, costs and area potential in Germany. Water-based Sphagnum farming is not recommended for large-scale implementation due to highest establishment costs, major cultivation risks and limited area potential. For soil-based Sphagnum farming, the most important cost positions were Sphagnum shoots to set up pilots, investment for water management and regular weed management. Bog grassland has the highest area potential, i. e. 90,000 ha in NW Germany. Paper V assesses the profitability of Sphagnum farming on former bog grassland based on extrapolating five years of field experience data (establishment ņ management ņ harvest) to a total cultivation time of twenty years. Cultivating Sphagnum biomass as founder material for Sphagnum farming or restoration was profitable even in pessimistic scenarios with high costs, high bulk density and low yields. Selling Sphagnum for orchid production was economically viable in the case of medium to high yields with a low bulk density. Cost-covering prices for Sphagnum biomass substituting peat seem achievable if end consumers pay a surcharge of 10 % on the peat-free cultivated horticultural end-product. An area of 35,000 ha of Sphagnum farming suffices to meet the annual demand of the German growing media industry for slightly decomposed Sphagnum peat.
Framework conditions affecting feasibility of paludiculture
The relation of revenues from selling biomass to its production costs is an important piece of the paludiculture feasibility puzzle. Further aspects effecting the economic viability and competitiveness of paludiculture encompass the market demand, the availability of mature technology, legal restrictions, the eligibility for agricultural subsidies, a remuneration of external benefits and the opportunity costs of present farming activities (Paper I, V). Legal and policy regulations are of major importance for land use decisions on peatlands – both for keeping up drainage and for shifting to paludiculture.
Conclusion and Outlook
This thesis provides a first assessment of the costs and profitability of large-scale harvesting of reeds and Sphagnum farming based on real-life data. The paludicultural practices investigated may be a solution for a minor share of the more than 1 million ha of peatlands drained for agriculture in Germany. Future research should also address other biomass utilisation options and other crops. Large-scale pilots are required to improve technical maturity of procedures and machinery, gather reliable data to replace assumptions on costs and revenues and study long-term effects on economics and ecosystem services. The micro-economic perspective needs to be complemented by the societal perspective quantifying and monetising external effects of peatland restoration, paludiculture and drainage-based peatland use. There is a high need for intensified research, large-scale implementation and accelerated adaption of the policy and legal framework to develop paludiculture as an economically viable option for degraded peatlands.
Interactions between bacteria and the human body are manifold and happen constantly. Most parts of the skin and gastrointestinal tract, the saliva, the oral mucosa, the conjunctiva and the vaginal mucosa are colonized with a multitude of bacterial species forming the human microbiota. Strikingly, the estimated amount of bacterial cells outnumbers the human body by 10 to 1. However, most of these bacteria colonize the human body without positive or negative effects and are regarded as commensals. Staphylococcus aureus a Gram positive bacterium is such a commensal bacterium of 25 % to 30 % of the world population. It is also an opportunistic pathogen and is able to cause infections in the lung, skin and heart and to induce sepsis. Its pathogenicity is mainly facilitated by the secretion of a broad spectrum of virulence factors which interact with the host. Some are distracting the immune system, others are targeting the host cell membrane or degrade macromolecular structures of the host in order to provide nutrients. Furthermore S. aureus is able to invade the host cell and to survive and replicate in the host cell cytosol or other compartments. The Gram negative proteobacterium Burkholderia pseudomallei is an environmental bacterium but still has the ability to enter the human body via body orifices or skin wounds. In a very efficient way it penetrates the host cell, replicates intracellular and the uses host structures to spread from cell to cell thereby causing the disease melioidosis often with fatal outcomes. Since the natural habitats of B. pseudomallei are wet soils, the change to the environment in the human body is drastic and requires a high degree of flexibility of the bacterium. Environmental stress conditions such as temperature, pH, nutrient limitation or presence of antibiotics induce a switch of colony morphology which is a special characteristic of this bacterium. Since it is assumed, that changes in colony morphology are connected to adaptive processes to the environmental changes, these morphology switches might also be important during infection. The host organism and the host cell on the other side try to kill and remove the bacterial threat by activating the immune system and cellular defence mechanisms. This includes generation of reactive oxygen and nitrogen species, production of antimicrobial peptides and cellular processes such as phagocytosis, autophagy, apoptosis and activation of the immune response. The actions and reactions on both, the pathogen side and the host side, are summarized as host-pathogen interactions. In the field of functional genomics, methods were developed to understand various levels of host-pathogen interactions. The holistic analysis of the mRNA (the transcriptome) or translated proteins (the proteome) were already very useful tools to describe important cellular processes on the host and the pathogen site. The level of metabolites with regard to host-pathogen interactions however, has been neglected so far. In this dissertation the metabolic composition in the intracellular and extracellular space of the host and the pathogen was analyzed. For this matter biochemical analytical tools were used such as 1H-nuclear magnetic resonance spectroscopy and chromatographic methods (GC and HPLC) coupled to mass spectrometry. The combination of these methods allows a broad coverage of physicochemical diverse metabolites. In accordance to the above mentioned biological levels like mRNA and proteins, the sum of all metabolites is referred as the metabolome. Consequently to transcriptomics and proteomics the analysis of the metabolome is referred as metabolomics. To gain insights into the infection relevant metabolome of the host-pathogen relationship between S. aureus and human lung cells several approaches were developed. First the distribution of the recently identified bacillithiol in different S. aureus strains was investigated with regard to its role during the infection. For that matter a HPLC-methodology was used with fluorescence based detection of labelled low molecular weight thiols (article I: Distribution and infection-related functions of bacillithiol in Staphylococcus aureus). After that the next aim was to reveal the effect of S. aureus on the host cell metabolism. To reduce the complexity of effects on the host cells an artificial model was chosen in a first approach. The lung cells were treated with the staphylococcal virulence factor alpha-hemolysin, a pore forming toxin and a holistic metabolomics approach was performed (article II: Staphylococcus aureus Alpha-Toxin Mediates General and Cell Type-Specific Changes in Metabolite Concentrations of Immortalized Human Airway Epithelial Cells). Using this approach, a protocol for cell culture metabolomics was established and first changes in the host cell metabolome that could be caused by S. aureus were described. However, this only describes specific changes caused by one single virulence factor and does not necessarily describes the reality during a S. aureus infection. Therefore in a next approach, an infection model using a human lung epithelial cell line and the S. aureus strain USA300 was established and used for metabolome analysis. Furthermore a combination of inhibitor treatment and metabolic labelling was used to clarify the metabolic activity in the host cell after exposure to S. aureus (article III: Metabolic features of a human airway epithelial cell line infected with Staphylococcus aureus revealed by a metabolomics approach). Finally this thesis deals with the host-pathogen interaction of B. pseudomallei and its host with a focus on the role of the switch in colony morphology in basic metabolism. Various morphotypes of two strains were generated by nutrient limitation and their uptake of nutrients was monitored. Furthermore the morphotypes were used in in vitro and in vivo infections and subsequently isolated out of the cell line and mice respectively. After isolation, the colony morphology was determined and again the nutrient uptake profile was monitored (article IV: Burkholderia pseudomallei morphotypes show a synchronized metabolic pattern after acute infection). The information provided by this thesis adds a new complexity to the knowledge about the host-pathogen interactions of S. aureus and B. pseudomallei and their hosts. It furthermore lays the groundwork for future studies, which will deal with these and other bacterial host-pathogen interactions in order to understand the interdependencies of infection and metabolism.
Objectives: Clear guidelines on when to remove an implant are missing. This study aimed to evaluate the amount of peri-implant bone loss at explantation by specialists.
Material and Methods: Implantology specialists were asked to provide implants explanted due to peri-implantitis with related clinical information. Questionnaires inquired age, sex, smoking habit, implant location, usage of bone substitutes, and implant brand. Early failures (survival time <12 months) were analysed separately. Explants were measured and bone loss and type of bone loss were assessed using radiographs. Bivariate analysis was used for the type of bone loss, and covariate-adjusted mixed-effects models were evaluated for the amount of bone loss and survival time.
Results: Twelve dental offices provided 192 explants from 161 patients with 99 related radiographs. Most implants were affected by vertical bone loss (51.1%), followed by combined horizontal and vertical bone loss (22.3%), peri-implant gap (11.7%), horizontal bone loss (10.6%), and only a few by apical inflammation (4.3%). Thirty-three (17.2%) explants were early failures. Type of bone loss was significantly associated with survival time and implant brand. Implant brand also showed a significant correlation with early/late implant failure. Excluding early failures, combined horizontal and vertical bone loss was additionally significantly associated with smoking, and the location when grouped to incisor, canine, premolar, and molar showed a significant association with the type of bone loss. Further, the average survival time was 9.5 ± 5.8 years with absolute and relative bone loss of 7.0 ± 2.7 mm and 66.2 ± 23.7%, respectively. Late failures were removed at a mean bone loss of 50.0% with 5.44 mm residual alveolar bone in the posterior maxilla and 73.8% with 2.89 mm residual alveolar bone in other locations. In fully adjusted mixed-effects models, only the age at implantation (B=-0.19; 95% CI: -0.27 to -0.10) remained a significant factor for survival time. Implants exhibited significantly more relative bone loss if they were positioned in the mandible (B=17.3; 95% CI: 3.91 to 30.72) or if they were shorter (B=-2.79; 95% CI: -5.50 to -0.08).
Conclusions: Though the mean bone loss (66.2%) at which implants were explanted was in accordance with the literature, its wide variation and differentiation between the posterior maxilla and other locations showed that the profession has no universally accepted threshold beyond which an implant cannot be preserved.
The relevance of cold atmospheric plasmas (CAPs) in biomedicine has recently grown. The potential of CAPs has been discussed in multiple scientific works, highlighting its effectiveness in promoting wound healing, limiting cancer progression, and for sterilization of surfaces. Main bioactive molecules, such as reactive oxygen and nitrogen species (RONS), are proposed as key candidates in these processes. Indeed, the generation of cold plasma induces noble gas ionization which, reacting with atmospheric air molecules, generates species such as singlet oxygen, atomic oxygen radicals, nitric oxide radicals. Although molecular simulations have been conducted, the mechanism of action on biological molecules, as well as the possibility to tune plasmas to produce specific species cocktails (e.g., with different degree of oxidation power) has been not fully unleashed. In this dissertation, presented in form of 5 published scientific articles, focus has been placed on the interaction of plasmas with peptides and proteins, which are main biological effectors in cellular compartments. Precisely, through the development of liquid chromatography coupled mass spectrometry (LC-MS) methods, the effects of plasmas on peptides and proteins in form of oxidative post-translational modifications (oxPTMs) has been investigated. The characterization of these oxPTMs has been performed by treating peptide or protein aqueous solutions and on porcine skin tissues. It has been found that, introducing small amounts of different gases (oxygen, nitrogen, or both) or even water molecules, can made CAPs tunable tools to produce oxygen-species dominating effects versus nitrogen-species dominating effects. In addition to this, it was found that the amino acid position in a peptide or protein influences the quality and quantity of the resulting oxPTMs. Besides this, other important parameters like driven gases, admixture gases or treatment duration were identified as relevant factors for the modification of amino acids in the peptide structure. By comparing the effects between peptide solutions and complex matrices such as porcine skin, water has been identified as a valid vehicle to transport and amplify the plasma chemistry. In an experimental study, the inactivation of a protein (PLA2) was observed after CAP treatment and together with simulation studies, the specific dioxidation of tryptophane W128 was detected as a potential explanation for this inactivation, indicating the strong impact of plasma on biological targets. In summary, oxidative modifications found in peptide solutions were observed also in complex protein structures and sample matrices. In conclusion, this work provides a starting point for future studies of oxidative modifications in complex models and may thus be helpful for further investigations in the fields of plasma medicine and redox chemistry.
Ebolaviruses are dependent on host cell proteins for almost all steps in their viral life cycle. While some cellular factors with crucial roles in the ebolavirus life cycle have been identified, many of them remain to be identified or fully characterised. This thesis focuses on the characterisation and identification of host cell interactions of the highly pathogenic Ebola virus (EBOV), probing host-virus interaction at various stages of the viral life cycle. Beginning with viral budding, the function of a recently proposed late domain motif within the EBOV matrix protein VP40 was examined using an EBOV transcription and replication-competent virus-like particle (trVLP) system. Although this motif has been suggested to interact with the endosomal sorting complex required for transport (ESCRT), we could show that this late domain motif does not contribute to EBOV budding.
While many host cell proteins have been identified so far that are important for viral budding, only a few proteins are known that are necessary for EBOV RNA synthesis. Thus, to identify host proteins that are involved in viral replication and transcription, we performed a genome-wide siRNA screen in the context of an EBOV minigenome assay. Using this approach, we identified several proteins that appear to be important for viral RNA synthesis or protein expression. Two of the most prominent hits in our screen were CAD (Carbamoyl-phosphate synthetase 2, aspartate transcarbamylase and dihydroorotase) and NXF1 (nuclear RNA export factor 1). CAD catalyses the first three steps in the de novo pyrimidine biosynthesis, while NXF1 is the main nuclear export protein for cellular mRNAs. In subsequent characterisation studies, using a range of life cycle modelling systems as well as molecular analyses, we could demonstrate that the canonical function of CAD during the pyrimidine biosynthesis is necessary for EBOV replication and transcription. In contrast to this, for NXF1 we discovered a so-far unknown function: Again, by applying different life cycle modelling alongside with molecular assays, we provided evidence that the EBOV nucleoprotein recruits NXF1 into inclusion bodies, the site of EBOV RNA synthesis, where it binds viral mRNAs to export them from these structures. Importantly, for both CAD and NXF1 we were able to recapitulate key data in the context of live EBOV infection, confirming their roles in the viral life cycle.
Both of these identified host factors are promising targets for antiviral therapies and indeed de novo pyrimidine synthesis is emerging as a possible antiviral target for a number of viruses. Similarly, as we could show NXF1 to be important in the life cycle of the highly pathogenic Junín virus, this raises the possibility that disruption of this interaction may result in broad-spectrum antiviral activity. Moreover, for an increasing number of negative-sense RNA viruses inclusion bodies as site of viral RNA synthesis are described to have a liquid organelle character. Therefore, our findings on NXF1 also provide an intriguing model to explain how negative-sense RNA viruses in general overcome this obstacle and export viral mRNAs from inclusion bodies.
Infrared laser absorption spectroscopy (IRLAS) employing both tuneable diode and quantum cascade lasers (TDLs, QCLs) has been applied with both high sensitivity and high time resolution to plasma diagnostics and trace gas measurements.
TDLAS combined with a conventional White type multiple pass cell was used to detect up to 13 constituent molecular species in low pressure Ar/H2/N2/O2 and Ar/CH4/N2/O2 microwave discharges, among them the main products such as H2O, NH3, NO and CO, HCN respectively. The hydroxyl radical has been measured in the mid infrared (MIR) spectral range in-situ in both plasmas yielding number densities of between 1011 ... 1012 cm-3. Strong indications of surface dominated formation of either NH3 or N2O and NO were found in the H2-N2-O2 system. In methane containing plasmas a transition between deposition and etching conditions and generally an incomplete oxidation of the precursor were observed.
The application of QCLs for IRLAS under low pressure conditions employing the most common tuning approaches has been investigated in detail. A new method of analysing absorption features quantitatively when the rapid passage effect is present is proposed. If power saturation is negligible, integrating the undisturbed half of the line profile yields accurate number densities without calibrating the system. By means of a time resolved analysis of individual chirped QCL pulses the main reasons for increased effective laser line widths could be identified. Apart from the well-known frequency down chirp non-linear absorption phenomena and bandwidth limitations of the detection system may significantly degrade the performance and accuracy of inter pulse spectrometers. The minimum analogue bandwidth of the entire system should normally not fall below 250 MHz.
QCLAS using pulsed lasers has been used for highly time resolved measurements in reactive plasmas for the first time enabling a time resolution down to about 100 ns to be achieved. A temperature increase of typically less than 50 K has been established for pulsed DC discharges containing Ar/N2 and traces of NO. The main NO production and depletion reactions have been identified from a comparison of model calculations and time resolved measurements in plasma pulses of up to 100 ms. Considerable NO struction is observed after 5 ... 10 ms due to the impact of N atoms.
Finally, thermoelectrically cooled pulsed and continuous wave (cw) QCLs have been employed for high finesse cavity absorption spectroscopy in the MIR. Cavity ring down spectroscopy (CRDS) has been performed with pulsed QCLs and was found to be limited by the intrinsic frequency chirp of the laser suppressing an efficient intensity build-up inside the cavity. Consequently the accuracy and advantage of an absolute internal absorption calibration is not achievable. A room temperature cw QCL was used in a complementary cavity enhanced absorption spectroscopy (CEAS) configuration which was equipped with different cavities of up to ~ 1.3 m length. This spectrometer yielded path lengths of up to 4 km and a noise equivalent absorption down to 4 x 10-8 cm-1Hz-1/2. The corresponding molecular concentration detection limit (e.g. for CH4, N2O and C2H2 at 1303 cm-1/7.66 μm) was generally below 1 x 1010 cm-3 for 1 s integration times and one order of magnitude less for 30 s integration times. The main limiting factor for achieving even higher sensitivity is the residual mode noise of the cavity. Employing a ~ 0.5 m long cavity the achieved sensitivity was good enough for the selective measurement of trace atmospheric constituents at 2.2 mbar.
(A paperback version is published by Logos under ISBN 978-3-8325-2345-9.)
Chiral amines represent high-value fine chemicals serving as key intermediate products in pharmaceutical, chemical and agrochemical industries. In the past decades, application of amine transaminases (ATAs) for stereoselective amination of prochiral ketones emerged to an environmentally benign and economically attractive alternative to transition metal-catalyzed asymmetric synthesis to afford optically pure amines at industrial scale. However, the restricted substrate scope of wild-type transaminases prohibited the conversion of particularly sterically demanding substrates, making protein engineering indispensable. The following thesis covers elaboration of a novel assay for transaminases (Article I) and identification and development of transaminase variants in order to achieve biocatalytic preparation of a set of pharmaceutically relevant model amines, ideally in optically pure form for both stereoisomers, preferentially using asymmetric synthesis and most preferably using isopropylamine as cost-efficient amine donor co-substrate (Article II-IV). The aforementioned target amines and the corresponding precursor ketones (see Scheme 4.1) were conceived and provided by the company F. Hoffmann-La Roche to attain suitable biocatalysts for a variety of potential intermediates for active pharmaceutical ingredients. Protein engineering of the transaminase scaffolds investigated in this thesis comprised: Initial screening for suitable starting enzyme scaffolds, structure-guided rational design of these scaffolds to enable bulky planar substrate acceptance, elaboration of a sequence motif, verification of the motif and preparative-scale asymmetric synthesis reactions (Article II). For non-planar and structurally different target substrates, namely spatially bulky or bi-cyclic bridged substrates, the transaminase variants were specifically refined and a different evolutionary route had to be pursued (Article III and Article IV). These results (Article II) represent not only the first successful endeavor to engineer a PLP-fold type I amine transaminase (commonly denoted as (S)-selective) for the conversion of highly sterically demanding substrates, but also generally expanded the scope of available fold type I amine transaminases by enzymes having a novel and exceptionally broad substrate spectrum. Aside from structure-guided rational protein engineering, as well non-rational methods, such as site-specific saturation mutagenesis or directed evolution, were applied for protein-engineering. In order to do so for all of the target compounds, a novel high-throughput solid phase activity assay for transaminases that was actually developed during the master thesis, was refined and published (Article I). In the context of this thesis, the same assay principle was as well adapted for quantification of specific activities in liquid phase (Article III). A comparison of different methodologies for developing agar plate assays and a detailed step by step protocol of our transaminase assay are illustrated in a book chapter.
The rapid anthropogenic climate change that is projected for the 21st century is predicted to have severe impacts on ecosystems and on the provision of ecosystem services. With respect to the longevity of trees, forestry in particular has to adapt now to future climate change. This requires profound multidisciplinary knowledge on the direct and indirect climate sensitivity of forest ecosystems on various spatial scales. Predictions on growth declines due to increasing drought exposition during climate change are widely recognized for European beech (Fagus sylvatica L.), which is the major forest tree in European temperate deciduous forests. However, research from other continents or other biomes has shown that winter climate change may also affect forest growth dynamics due to declining snow cover and increased soil cooling. So far, this winter cold sensitivity is largely unexplored in Europe. Thus, particularly focussing on forest growth dynamics and winter cold sensitivity, the goal of this PhD-project was to explore how climate sensitivity of forest ecosystems differs regionally. By doing so, the project aimed to deliver insights about possibilities and limits of upscaling regional knowledge to a global understanding of climate sensitivity. To achieve these goals, this PhD-project integrated five studies (Manuscripts 1–5) that investigated the climate sensitivity of biogeochemical cycles, plant species composition in forests, and forest growth dynamics across spatial scales. In particular, a large-scale gradient-design field experiment simulated the influence of winter climate change on forest ecosystems by snow cover and soil temperature manipulations (Manuscript 1). This study indicated that soil cooling and decreased root nutrient uptake may indirectly reduce growth of adult forest trees. Moreover, this study indicated uniform ecological sensitivity to soil temperature changes across sites along a large winter temperature gradient (ΔT = 4 K across 500 km), irrespective of the site-specific history of snow cover conditions, which motivates upscaling from local winter climate change studies to the regional scale. Although regional climate drives growth of adult forest trees, local factors, such as site-specific edaphic conditions, might control plants in the forest understory. This assumption was tested by mapping the forest understory composition along the same winter temperature gradient as introduced above (Manuscript 2). Across sites, this study found that edaphic conditions explained the spatial turnover in the forest understory composition more than climate, which might moderate direct climate change impacts on the forest understory composition. However, edaphic conditions, forest structure, and climate are linked by triangular interactions. Thus, climate change might still indirectly affect the forest vegetation dynamics. Moreover, a dendroecological study focussed on the same winter temperature gradient from central to cold-marginal beech populations as above in order to identify gradual changes in summer drought and winter cold sensitivity in tree growth (Manuscript 3). Towards the cold distribution margin, the influence of drought on tree growth gradually decreased, while growth reductions were increasingly related to winter cold due to harsher winter climate. By a large-scale dendroecological network study assessed the relationship of growth dynamics to climate and reproductive effort in beech forests across Europe (Manuscript 4). Indeed, this study found the general pattern across the distribution range of beech that high temperature controlled growth indirectly via resource allocation to reproduction. However, the strong, direct drought signal that could be generally detected from dry-marginal to central populations vanished towards the cold-marginal populations, where the more focussed study of Manuscript 3 identified a stronger relationship of tree growth to winter cold. Further extending the scope of this PhD-thesis to global scales, litter decomposition rates were assessed across biomes (Manuscript 5). This study found a robust relationship between climate and decomposition rates, but it also demonstrated large within-biome variability on a local scale. These local scale differences might depend on habitat conditions that, in turn, could be modulated by climate change, which calls for a better exploration of indirect climate sensitivity. In conclusion, this PhD-thesis highlighted that multidisciplinary research can advance the understanding of ecological interactions in forest ecosystems under changing climate scenarios. In this PhD-project, a winter climate change experiment, where site-representative target trees were selected by means of dendroecology, contributed to a mechanistic understanding of winter cold sensitivity in forest growth dynamics. Dendroecological investigations then put the findings in a broader temporal and spatial context by describing local climate sensitivity of tree growth on different spatial scales. This thesis further shows that global generalizations about the relationship of climate and ecological processes in ecosystem models have to be critically reviewed for the need of local and regional adjustment because these processes might experience considerable regional- or local-scale variation. However, this thesis reports uniform sensitivity of ecological processes to altered winter soil temperature regimes across a large winter temperature gradient. Thus, upscaling from insights of previous winter climate change experiments to regional scales is encouraged.
The Black Sea experienced fundamental environmental changes during the last glacial-interglacial transitions. During the last 670,000 years, the Black Sea was at least twelve times connected to Mediterranean Sea, received saltwater via the Bosporus strait, and evolved to a brackish anoxic water body. A lowered global sea level during glacials caused isolation of the basin from the open ocean, and the Black Sea became limnic and well-oxygenated. The last glacial-interglacial history of the Black Sea is relatively well understood and demonstrates the high sensitivity of this basin to global climate and environmental changes. Previous studies particularly focussed on the evolution during the last glacial with meltwater pulses, warming during the glacial-interglacial transition, and the development from a ventilated lake to the present euxinic/brackish water body. Apart from the interglacial warming, the Black Sea sediments clearly recorded short-term abrupt temperature changes associated with cooling during Heinrich events and the Younger Dryas as well the Bølling-Allerød warming, which occurred over the northern hemisphere. However, our knowledge about the Black Sea history before 40,000 BP is comparatively poor even though crucial for understanding hemisphere-wide atmospheric teleconnection patterns and climate mechanisms during older glacials and interglacials. A multiproxy approach has been applied on three gravity cores and surface sediment from the southeastern Black Sea comprising ostracod geochemistry (Mg/Ca, Sr/Ca, U/Ca, 87Sr/86Sr), major and trace elements (Al, Ca, Fe, K, Ti, Mo, Re, Sr, W, Zr) and organic biomarkers (n-alkanes, alkenones, UK’37-palaeotemperatures, glycerol dialkyl glycerol tetraethers, TEX86-palaeotemperatures, BIT-index). The cores cover the last 134,000 a and provide new findings concerning the last and penultimate glacial-interglacial transitions (12,000- 0 a BP; 134,000-120,000 a BP) as well as the abrupt climate changes during the last glacial period (64,000-20,000 a BP). The major topics of this work are i) the penultimate glacial-interglacial transition (Saalian-Eemian), ii) the environmental conditions in the Black Sea “Lake” during abrupt climate oscillations of the last glacial period, iii) and the comparison of the redox evolution during Eemian and Holocene sapropel formation. Two meltwater pulses caused a pronounced freshening of the Black Sea “Lake” during the ending penultimate glacial, which originated from the melting Fennoscandian Ice Sheet. Due to unusually high radiogenic Sr-isotope signatures of benthic ostracods, a potential Himalayan source communicated via the Caspian Sea is also likely. During the glacial-interglacial transition the temperatures in the Black Sea increased from 9°C to 17°C and the associated global sea-level rise allowed the reconnection between the Mediterranean and Black Seas around 128,000 a BP. Eemian sapropel formation started shortly after the intrusion of saltwater and the water body became gradually euxinic. In comparison with the Holocene sapropel, the Eemian proxy records imply warmer and stronger euxinic conditions and distinctly higher enrichments of redox-sensitive trace elements like e.g. Mo, Re, and W. Because the seawater forms the ultimate source for several trace metals, these enrichments were most likely favoured by the higher salinity due to a ca. 10 m higher sea level and enhanced Mediterranean Sea - Black Sea water exchange. Based on biomarker analyses, lake surface temperatures could be calculated for the first time for the period between 64,000 and 20,000 a BP, which includes the Marine Isotope Stage (MIS) 3. Abrupt stadial/interstadial temperature changes with amplitudes of up to 4°C in the Black Sea “Lake” clearly resemble the Greenland Dansgaard-Oeschger pattern. However, an exceptional cooling during the so-called Heinrich events is not evident from our cores. This finding agrees with modelling results proposing a deeper penetration of regular Dansgaard-Oeschger cycles into the Eurasian continent when compared with the Heinrich events. During the warm and more humid interstadials, the Black Sea “Lake” became fresher and more productive and the water level probably increased. During the colder and more arid stadials the freshwater supply was decreased and productivity was low. Aridity and stronger westerly winds favoured the input of aeolian transported detritus. The long-term pattern from 64,000 to 20,000 a BP demonstrates a strong influence of orbital-driven changes in the Eurasian ice volume and associated atmospheric circulation patterns over the Black Sea region. The present multi-proxy study demonstrates that the sediments from the SE Black Sea clearly record not only orbital- but also millennial-scale climate and environmental changes and thus represent an important continental archive for climate change bridging the North Atlantic-Eurasian corridor.
Comprehensive study of the discharge mode transition in inductively coupled radio frequency plasmas
(2016)
In this contribution, the mode transition of an inductively coupled radio frequency plasma at low pressure is investigated. Therefore, a comprehensive set of plasma diagnostics were applied to determine plasma and processing parameters. Therewith, the plasma kinetics and especially the important elementary processes were studied. Hence, the reason for the mode transition was identified.
Computational chemical physics can give important input to astrophysical modelling and other fields of physics, where molecular properties are of importance. Understanding of spectroscopic and reactive behaviour is crucial for many systems of astrophysical interests like stars, interstellar medium and comets. Especially stellar atmospheres are of interest, because the complex physics of stars are not yet completely understood. Stars are in an unstable balance of gravitation and radiation pressure and the atmospheric dynamics have been subject of extensive modelling. Complete and accurate spectroscopic information of the atoms and molecules in these atmospheres is necessary for this attempt. In addition, the only information we have about astrophysical systems is light which is emitted or absorbed by particles in these media. This is not only true for astrophysics. In plasma physics sometimes the usage of invasive diagnostics, like Langmuir probes, is not wanted because they disturb the system. In these cases some information of the system can be regained by passively measuring infrared spectra of the plasma or by active induction of electronic transition like the laser-induced fluorescence method. Another remote sensing application is the measurement of the atmospheric composition on earth. Here, larger particles in the atmosphere as well as greenhouse gases are of current interest. Unfortunately, the experimental spectroscopic data, which is needed for the understanding and interpretation of the measured spectra, is often incomplete. This gap can be, to some extend, filled by computational chemical physics. The aim of this work was to investigate the capabilities and limitations of ab initio based potential energy surfaces for spectroscopic and reactive studies and to apply these methods to problems of rovibrational and rovibronic spectroscopy and reaction dynamics. The choice of ab initio methods and the potential fitting methods is critical for the computational chemical physics, as all further quantities directly depend on their quality. In this work modified versions of the Braams polynomial potential energy surface were used. A high level coupled cluster ab initio method was used to build potentials for a series of small hydrocarbons. Hydrocarbons can be found almost everywhere on earth and in the universe. They exist in laboratory plasmas, stellar and planetary atmospheres and interstellar gases. In all these cases, light emitted or absorbed by the molecules is an important diagnostics of the system. The potential constructed in this work partly included a cluster expansion, which adds reactant configuration spaces to the fits. This could not be done for CH_3 and higher hydrocarbons, because of the limitations of the Coupled Cluster ab initio method, which is well suited for the potential wells, but not for the dissociation regions. The examples of methyl and methane show how the potentials can be used for rovibrational spectroscopy. Results of radiation transport simulations illustrate the importance of as complete-as-possible line lists for radiation transport calculations.\\ The rovibronic spectroscopy of diatomic molecules is another important aspect for the stellar atmospheric modelling. Metal hydrides and oxides add opacity to the atmosphere in the visible light and ultraviolet frequency regions, as well as do the hydrocarbons in the infrared one. In addition the spectra of metal hydrides/oxides can be used to gather information about metal and their isotope abundances. They are used as markers for the conditions in the atmospheres of stars. In this work a new code was developed, that efficiently calculates bound-bound transitions between electronic states and bound-continuum cross sections for diatomic molecules. It also offers an adequate treatment of quasi-bound rovibrational states. One important representative of the diatoms is magnesium hydride, MgH. Before this work, line lists and photodissociation cross section were available involving the three lowest doublet states of MgH. In this work new potential energy curves were calculated and adapted to updated experimental data. This causes changes in the relative energies between the electronic states and therefore shifts in the line lists. These are important, because accurate line positions are needed for the identification of spectral lines. In addition two further electronic states were included in the calculations. This expands the spectral range of MgH into the near ultraviolet region. Radiation transport models showed significant absorption by MgH from the newly added electronic states. A second usage of the diatomic potential energy curves are photodissociation cross sections. As interstellar environments are chemically active, such data is necessary for a complete picture of the ongoing processes. The photodissociation cross sections of MgH reveal a stronger dependence of the underlying potential than the bound-bound lines. In the case of MgH the cross sections are rather weak, besides occasional resonance lines which can be several orders of magnitude stronger. As mentioned, not only spectroscopic, but also reactive behaviour of molecules is important in astrophysics. A current problem connected with this is the abundance of CH^+ in interstellar clouds. Its measured abundances do not fit the predictions from theoretical models. In addition Gerlich and co-workers recently measured low temperature H + CH^+ -> C^+ + H_2 reaction rates, which diverge from the theoretical picture and which could not be explained. In this work a reactive potential energy surface was built for the CH_2^+ system, which was then used to perform extensive calculations with quasi-classical trajectory and quantum scattering methods. It was found out, that the potentials used in previous works are not accurate enough to allow low temperature calculations. Results from these potentials must be taken with care. Furthermore, the results from the new potential energy surface indicate significantly reduced reaction rates compared to previous numerical studies. This is in agreement with the new results of Gerlich and co-workers. Nevertheless, the large error bars in the low temperature range for experimental as well as numerical results strongly suggest refined methods to be developed for both, before a final conclusion can be made. This work demonstrated the possibility of modern computational chemical physics to supply consistent data for spectroscopy and reaction dynamics. These are necessary and important inputs for fields like astrophysics, plasma physics and chemistry.
Background and objective
The COVID-19 pandemic started in Wuhan, China, in December 2019. Although there are some doubts about the reporting of cases and deaths in China, it seems that this country was able to control the epidemic more effectively than many other countries. In this paper, we would like to analyze the measures taken in China and compare them with other countries in order to find out what they can learn from China.
Methods
We develop a system dynamics model of the COVID-19 pandemic in Wuhan. Based on a number of simulations we analyze the impact of changing parameters, such as contact rates, on the development of a second wave.
Results
Although China’s health care system seems to be poorly financed and inefficient, the epidemic was brought under control in a comparably short period of time and no second wave was experienced in Wuhan until today. The measures to contain the epidemic do not differ from what was implemented in other countries, but China applied them very early and rigorously. For instance, the consequent implementation of health codes and contact-tracking technology contributed to contain the disease and effectively prevented the second and third waves.
Conclusions
China’s success in fighting COVID-19 is based on a very strict implementation of a set of measures, including digital management. While other countries discuss relaxing the lock-down at a rate of 50 per 100,000 inhabitants, China started local lock-downs at a rate of 1.59 per 100,000. We call for a public debate whether this policy would be feasible for more liberal countries as well.
Multiply negatively charged aluminium clusters and fullerenes were generated in a Penning trap using the "electron-bath" technique. Aluminium monoanions were generated using a laser vaporisation source. After this, two-, three- and four-times negatively charged aluminium clusters were generated for the first time. This research marks the first observation of tetra-anionic metal clusters in the gas phase. Additionally, doubly-negatively charged fullerenes were generated. The smallest fullerene dianion observed contained 70 atoms.
In acinar cells, cellular organelles like zymogene granule, mitochondria, endoplasmic reticulum and lysosome functions in coordinate way in order to synthesize and secrets large amounts of digestive enzyme. Dysfunction of this organelle, results into enzyme activation within acinar cell; ultimately, acute pancreatitis. While previous studies reported that mitochondrial function is disrupt but mechanism of clearance of these mitochondria remains unknown during pancreatitis. Here we reported that PINK1 and Parkin mediated pathway is activated during pancreatitis and clears dysfunctional mitochondria in-vivo. PINK1 or Parkin deficient acinar cell had energy crisis, decreased ATP production and altered acinar cell fate in-vitro. Inhibiting clearance of dysfunctional mitochondria aggravates experimental pancreatitis severity and delays regeneration/recovery of exocrine tissue after disease via PARIS-PGC-1α pathway. While an attempt to explore therapeutic target of PARIS-PGC-1α pathway by treatment of SRT1720 rescued experimental pancreatitis. Together, PINK1 and Parkin, restricts exocrine pancreatic damage in pancreatitis and accelerates tissue recovery after disease.
The New Zealand coal covering the complete maturity range from peat to high volatile bituminous, thus from early diagenetic to catagenesis coalification levels, has been studied in order to bring out new insights into molecular alterations, macromolecular structural evolution, elemental-compositional changes as function of maturation and to propose which processes cause these changes. As particular note from the previous observations that many immature coals from around the world often have rather high extraction yields. It is uncertain whether or not bitumen affecting on petroleum potential and structural evolution of coals. My purposes were therefore to find out the possible interaction between kerogen and bitumen during pyrolysis, and to elucidate the role of bitumen in defining petroleum potential and structural evolution of coals. Furthermore, it is assumed that low rank coals appear to be well suited for feeding the deep subsurface microbes. The products are released as either CO2 or CO that could be substrates for microbial activity. Thus, in this dissertation, I have calculated the loss of CO2 during diagenesis to give the quantitative feeding potential link to deep biosphere, using a mass balance model. To achieve these purposes, at the primary step, the facies variability as well as the molecular compositional changes within the coal band sequence in regard to distinguish the influences of organofacies and maturity need to be clear. Hence, the first aim was to gather information about depositional environment and insights into the plant communities that have contributed to New Zealand coals. Numerous organic-geochemical techniques were used to analyse the free lipids and macromolecular organic matter. Total organic carbon determination (TOC), bulk δ13Corg isotope analysis, the Rock-Eval pyrolysis, pyrolysis- gas chromatography and infrared spectrometry were performed on the original samples and the residue after solvent extraction. The crude lipid extract was separated into fractions that were then analysed by gas chromatography and gas chromatography-mass spectrometry. The obtained data shows that organic matter of New Zealand coals contains mainly terrestrial higher plant material, with a more or less constant background supply of bacterial biomass, deposited in oxidising environment. Angiosperms contributed as the main proportion of the organic matters. Gymnosperms, particularly the Podocarpaceae, Cupressaceae, Taxodiaceae, Pinanceae and Araucariaceae conifer species, still dominated during the Cretaceous. New Zealand coal is classified as mixed gas- and oil-prone. Hydrogen index values increase from 120 to 280 (mg/g TOC) with increasing maturity, which has been explained by the loss of oxygen during diagenesis. A Transformation Ratio of CO2 (TRCO2) has been formulated here in order to quantify the loss of CO2 for any given coal type. It obviously shows CO2 generation is one of the major features of diagenesis that might feed the deep biosphere. In case of study, about 10 to 105 mg CO2 per gram of total organic carbon have been released during maturation from peat to high volatile bituminous. This is equivalent to 0.23 to 2.4 millimoles CO2 per g TOC. For methanogenesis via CO2 reduction, between 0.92 and 9.6 millimoles hydrogen would be required for complete CO2 reduction during diagenesis. Future work must determine if this is feasible or not. The important role of bitumen in defining the petroleum generation potential was elucidated. The presence of hydrogen transfer agents in bitumen helps to stabilize free radicals hence prevents recombination/ repolymerization processes thus preserving the petroleum generating potential in original coals. Specially, second-order reactions between kerogen and bitumen occurred during pyrolysis that reduce the primary gas yield, but increase the potential secondary gas as well as oil yields. Therefore, it is proposed that pre-extraction of source rocks before pyrolysis, especially coals where extraction yields are particularly high, is not recommended. The comparative investigation with previously studied higher rank Carboniferous German coals showed an excellent fit for both pyrolysis and infrared spectrometry data, suggesting that the New Zealand coals can be considered as natural precursors of the German coals. The structural evolution of coals during maturation is firstly characterized by the enrichment of the aliphatic structures in low rank, peat to high volatile bituminous, then decreases with further maturation. This enrichment of aliphatic carbon content in low rank is accompanied by an increase in the average aliphatic chain length. A slightly enrichment of CH3 group is observed in maturity range 0.9- 2.1% vitrinite reflectance. Secondly, during coalification the content of protonated aromatic carbons increases until R0 ~ 1.6%, then decreases with further maturation.
Staphylococcus aureus is present in around a third of the human population as a constant commensal in the anterior nares, in a third as an intermittent commensal, and a third are non-carriers. However, S. aureus is also a dangerous pathogen, responsible for many types of infections. Recently, the emerging of methicillin-resistant S. aureus strains has aggravated the health problem. Treating infections caused by the invasive strains has become ineffective with conventional antibiotics. Noticeably, transmission of S. aureus has occurred not only in healthcare settings but also in the community; furthermore, transmission between humans and domestic animals has been reported. Although studies about host-pathogen interactions of S. aureus have advanced our knowledge in the last decades, we still have not fully understood mechanisms of the immune system in responses to S. aureus. The aim of this study is to unravel interactions of the human adaptive immune system to selected S. aureus virulence factors. In particular, the study focuses on two aspects: the reaction of human antibodies to the bacterial extracellular proteins in S. aureus-induced furunculosis with an emphasis on Panton-Valentine Leukocidin and responses of the adaptive immune system to membrane-bound lipoproteins of S. aureus. Furunculosis is a variety of hair follicle infection in which S. aureus is one of the chief causal pathogens involved. The corresponding bacterial strains are generally capable of producing of a pore-forming toxin, known as Panton-Valentine Leukocidin (PVL). Recently, the emerging of pvl-positive methicillin-resistant S. aureus has become a problem for treating the bacterially caused furuncles. Colonization with the bacteria is a risk factor for development of chronic or recurrent boils. It is not yet known why furunculosis patients are largely infants or young adults. In this context, we untangled the responses of antibody IgG antibodies to S. aureus extra-cellular factors, notably the PVL toxin, in families in which the patients were children. Multiplex PCR demonstrated that S. aureus clones, isolated from the patients’ wounds but also from the nares of family members, harbored genes coding for PVL toxin. Spa-typing highlighted that bacterial genotypes were very similar in each family. This suggests that transmission of pvl-positive S. aureus took place between family members. The finding also raises the question why only the young patients but not family members who were colonized by the same S. aureus clones suffered from furunculosis. 2D immune proteomics procedures showed a tendency of higher IgG titers against bacterial virulence factors in family healthy members than in patients. PVL-specific antibodies were measured using ELISA, in which patients’ PVL-specific IgG titers were low. This supports the idea that antibodies, probably in conjunction with T cells, might contribute to clinical protection in furunculosis. This research will serve as a foundation for future studies, in which our results should be validated in a larger cohort. Among S. aureus’ virulence factors are lipoproteins, which are anchored in the bacterial cell membrane. Lipoproteins perform various functions in colonization, immune evasion, and immunomodulation. These proteins are potent activators of the complex of innate immune receptors termed Toll-like receptors (TLR) 2 and 6. This study addressed the specific B-cell and T-cell responses to lipoproteins in human S. aureus carriers and non-carriers. 2D immune proteomics and ELISA approaches revealed that titers of serum antibody (IgG) binding to the S. aureus lipoproteins were very low or even unmeasurable in healthy individuals except for the lipoprotein SaeP. Only patients with cystic fibrosis or epidermolysis bullosa who were heavily exposed to the bacteria, generated an antibody response also to lipoproteins. Proliferation assays and cytokine profiling data showed only subtle responses of T cells in healthy individuals; three out of eight tested lipoproteins did not elicit proliferation. Hence, the robust activation of the innate immune system by S. aureus lipoproteins does not translate into a strong adaptive immune response. Reasons for this may be inaccessibility of lipoproteins for B cells as well as ineffective processing and presentation of the antigens to T cells. The main findings implicate that family members can serve as S. aureus reservoirs causing recurrent furunculosis in young patients and that antibodies may provide partial protection from such infections by S. aureus. We have found that, different from proteins that are secreted by S. aureus, lipoproteins which anchored in the bacterial cell membrane, do not trigger strong responses from the human adaptive immune system. This suggests that these proteins remain mostly hidden in the bacterial cell-wall.
In 2010, the identification of 17 novel (R)-ATAs represented a breakthrough for the biocatalytic asymmetric synthesis of chiral amines, because only one (R)-ATA was described before. These novel ATAs were identified in a bioinformatic approach by studying the substrate acceptance of BCATs and DATAs to deduce the unknown substrate coordination of (R)-ATAs. Article I describes an alternative approach for the identification of (R)-ATA activity by reengineering the substrate- recognition site of α-AATs. While the engineering of the eBCAT led to the formation of an initial (R)-amine acceptance only, the (R)-ATA activity was successfully introduced in the DATA scaffold. These results demonstrate the transformation of an α-AAT in a moderately active (R)-ATA for the first time and highlight the evolutionary relationship between α-AATs and ATAs. Despite the availability of different ATAs nowadays, their substrate spectrum is limited due to the natural composition of their active sites. Several protein-engineering studies showed the widening of the substrate spectrum and the acceptance of bulky substrates by screening large mutant libraries to identify beneficial variants. In Article II, we developed an in silico engineering approach for amine transaminases to improve the conversion of bulky substrates and to reduce the number of variants to be tested in the laboratory. The resulting double-mutants of the (S)-ATA from C. violaceum displayed a >200-fold improved activity towards the bulky benchmark substrate. These variants expand the available biocatalytic toolbox for the synthesis of bulky amines, and the developed framework paves the way for rational protein-engineering protocols.
By studying unconventional transaminase substrates, we explored the potential of the available in- house transaminase toolbox in Articles III, IV, V, and VI. In Article III, we showed the transamination of a β-keto ester, leading to the synthesis of β-phenylalanine. The described cascade in Article IV enables the synthesis of amino carbohydrates. In addition, Article V describes an enzymatic cascade for the synthesis of amino fatty acids, which was extended in Article VI to obtain fatty amines.
The findings of this thesis clearly contribute to the understanding of the substrate scope and specificity of amine transaminases and expand the application of this versatile biocatalyst beyond classical ketone substrates.
Immunogenicity and protectivity of surface-localized lipoproteins of Streptococcus pneumoniae
(2019)
Steptococcus pneumoniae (pneumococcus) represents a common colonizer of the human upper respiratory tract (URT). However, under certain conditions, for example following viral infections, or in indiciduals with a weakened immune system, including young children, elderly and immunocompromised persons, it can cause a wide range of life-threatening diseases, such as pneumonia, meningitis or sepsis. Based on the polysaccharide capsule that surrounds the bacterium, pneumococci are classified into so far 98 different serotypes. Prevention of S. pneumoniae infections was achieved by the development of pneumococcal polysaccharide-based (PPSV) vaccines. However, these vaccines have important limitations, including high manufacturing costs and restricted serotype coverage facilitating replacement by non-vaccine serotypes. Aiming for the development of a serotype-independent vaccine, the potential of surface-exposed and highly conserved pneumococcal lipoproteins was evaluated for being targeted as a future protein-based vaccine. Therefore, selected lipoproteins were examined i) for their surface abundance and accessibility, ii) for their presence in clinically relevant S. pneumoniae strains, and iii) for their immunogenicity. Finally, based on these initial screenings, the most promising candidates were selected to analyze their protective efficacy in a moude model of colonization. DacB and PnrA were identified as highly abundant lipoproteins on the pneumococcal surface. They showed to be immunogenic both during natural infection using convalescent patient sera and when given to mice as a subunit vaccine formulation. Following intranasal immunization and challenge of mice with two heterologous S. pneumoniae strains, both proteins reduced the pneumococcal load in the nasopharynx. The protection correlated with increased production of IL-17A indicative for a Th17-mediated immunity, which is strongly suggested to play a critical role in preventing pneumococcal colonization and infection. Lipoproteins are triggering innate receptors on antigen-presenting cells, thereby linking innate with adaptive immune responses. Therefore, lipidated proteins were evaluated for their potential to be used as an adjuvant for vaccination. Lipidation clearly enhanced humoral immune responses to DacB and PnrA without the need of an additional adjuvant. However, an additional adjuvant was required to confer protection against pneumococcal colonization. In conclusion, Lipoproteins are interesting candidates for future protein-based vaccine strategies because they are highly conserved, abundant and immunogenic. PnrA and DacB were identified as potential candidates, since they induced protection against pneumococcal colonization, which in turn may lead to a decline in infections and transmission.
This work investigated the enzymatic degradation of polyethylene terephthalate (PET) (ArticlesI and II) and polyvinyl alcohol (PVA) (Article III). Physical or chemical degradation of plastic polymers is often performed under extreme conditions like high temperatures or pressure. In comparison to that, recycling of plastics with enzymes can be carried out at ambient temperatures and neutral pH. Enzymes themselves are non- toxic, environmentally friendly, and have been used successfully in a variety of industrial processes.
Enzymatic degradation of polyesters is well studied. Their heteroatomic backbone, which is connecting monomers via ester bonds offers a target for an enzymatic attack. Especially PET, one of the most common polyesters, has been in the focus of research. The first enzyme capable of degrading the polymer was found in 2005. Since then, researchers discovered several enzymes with similar functions and subjected them to enzyme engineering. Improving the enzyme's substrate affinity, activity, and stability aims at making PET recycling more efficient. Article I provides an overview of limitations that enzymatic PET recycling is still facing and the research carried out to overcome them. More precisely, enzyme−substrate interactions, thermostability, catalytic efficiency, and inhibition caused by oligomeric degradation intermediates are summarized and discussed in detail.
Article II further addresses one of the above-mentioned limitations, namely product inhibition of PET hydrolyzing enzymes. We elucidated the crystal structure of TfCa, a carboxylesterase from Thermobifida fusca (T. fusca), and applied semi-rational enzyme engineering. The article discusses the structure-function relationship of TfCa based on the apo-structure as well as ligand-soaked structures. Furthermore, it compares the structures of TfCa and MHETase, another PET hydrolase helper enzyme. Lastly, we determined the substrate profile of the carboxylesterase based on terephthalate-based oligo-esters of various lengths and one ortho-phthalate ester. In a dual enzyme system, TfCa degraded intermediate products derived from the PET hydrolysis of a variant of PETase hydrolase from Ideonella sakaiensis (I. sakaiensis). The dual enzyme system utilized PET more efficiently in comparison to solely PETase due to relieved product inhibition. Since TfCa successfully degraded oligomeric intermediates, the reaction not only released terephthalic acid as the sole product but also increased the overall product yield.
While PET contains an ester bond that can be attacked and hydrolyzed by esterases or lipases, PVA consists of a homoatomic C-C-backbone with repeating 1,3-diol units. The polymer is water soluble with remarkable physical properties such as thermostability and viscosity. PVA is often described as biodegradable, but microbial degradation is slow and frequently involves cost-intensive cofactors. In this study, we present an improved PVA polymer with derivatized side chains and an enzyme cascade that can degrade not only modified but also unmodified PVA in a one-pot reaction. The enzyme cascade consists of a lipase, an alcohol dehydrogenase (ADH), and a Baeyer-Villiger monooxygenase (BVMO). In comparison to the scarcely published research on PVA degradation with free enzyme, this cascade is not only independent from the frequently required cofactor pyrroloquinoline quinone (PQQ) but, in principle, contains an in vitro cofactor recycling mechanism.
Background: Physical inactivity is one of the main risk factors for cardiovascular disease,
which remains a major cause of death in Germany and around the globe. Thus, investigating
prevalences, population trends, high-risk groups, and intervention effects of physical activity
(PA) and sedentary time (ST) is highly relevant to public health. To receive reliable data, a
key issue in research is to apply an appropriate study design including the carefully
considered use of assessments. Otherwise, bias to PA and ST data may be introduced. The
present thesis investigates three often overlooked issues related to the impact of measurement
on PA and ST research data. The first aim was to examine whether mere measurement alters
PA and ST over the course of twelve months (study 1). The second aim was to identify
potential socio-demographic and cardiometabolic moderators of the mere-measurement effect
(study 2). The third aim was to present design, protocol, and preliminary results of an interim
analysis of a randomized controlled trial (RCT) aiming to test whether a video demonstration
of PA intensity levels reduces the lack of agreement between self-reported and objectively
measured PA (study 3).
Methods: Studies 1 and 2 were based on data of a trial to test the feasibility of a brief tailored
letter intervention to increase PA and to reduce ST during leisure time. Among a sample of
subjects with no history of myocardial infarction, stroke, or vascular interventions, a number
of 175 individuals aged 40 to 65 years participated in the study. At baseline, participants
received standardized measurement of blood pressure and waist circumference, blood sample
taking, and seven-day accelerometry. At baseline and after one, six, and twelve months,
participants completed the International Physical Activity Questionnaire (IPAQ). A random
subsample received a brief tailored letter intervention at months one, three, and four. A
number of 153 participants were included in study 1 using all available data across 12 months.
Changes in PA and ST were analyzed using latent growth modeling. For study 2, baseline and
one-month follow-up data of 175 participants were used. Dependence of one-month changes
in PA and ST on socio-demographic and cardiometabolic variables was analyzed using linear
regression models. In study 3, individuals aged between 40 and 75 years were recruited at a
shopping mall in Greifswald, Germany. Participants received seven-day accelerometry and
were invited to the cardiovascular examination center of the University Medicine Greifswald.
After random allocation to experimental and control group, they completed the selfadministered
IPAQ – Short Form via tablet-computer. The experimental group additionally
received a video demonstration of PA intensity levels before answering the questionnaire. A number of 131 participants were analyzed to receive preliminary results of an interim analysis
in order to verify the presumptions made for the a priori power calculation and to decide on
early stopping of the study. The difference between the study groups in the agreement
between self-reported and accelerometer-based PA was analyzed using a two-sample t-test.
Results: In study 1, results revealed no change in leisure-time PA, an increase in transportrelated
PA (p = .023), and a tendency towards a reduction of ST (p = .060) between baseline
and one-month assessment. Further, ST decreased between six and twelve months (p = .037).
Time trends of the intervention group did not differ significantly from those of the
assessment-only group. Results of study 2 revealed that men increased transport-related PA
more than women (p = .031) and men with higher triglycerides increased transport-related PA
less than men with lower triglycerides (p = .043). Men with higher systolic blood pressure
reduced ST more than those with lower systolic blood pressure (p = .028). However, this
linear association ceased to exist at a level of approximately 145 mmHg. A similar
relationship was found for glycated hemoglobin and ST in men. In study 3, preliminary
results of the interim analysis revealed a lower formal mean difference in the video group (M
= 21.8 min/day, SD = 108.9) compared to the control group (M = 41.0 min/day, SD = 117.4,
t(129) = 0.97, p = .166). The p-value lay between the significance (p < .010) and futility (p >
.269) boundaries of the test simulations.
Conclusions: Results of the present thesis have three implications for considering the impact
of PA and ST assessments in cardiovascular research. First, mere-measurement effects within
a feasibility trial were found in transport-related PA and ST suggesting to interfere with
potential intervention effects. Thus, measurement effects should be considered when planning
studies and interventions and when interpreting outcomes. Second, male sex and more
favorable triglycerides levels in men were associated with a higher increase of transportrelated
PA whereas worse health in men was associated with a higher reduction of ST. Thus,
using the mere-measurement effect for prevention purposes may require researchers and
practitioners to tailor PA and ST intervention components to individuals’ health condition.
Third, the design and protocol of the RCT seems appropriate to test the effect of a novel video
on the gap between self-reported and accelerometer-based PA. Preliminary results point to the
efficacy of the video.
Multiple sclerosis (MS) and stroke share a number of mechanisms of neuronal damage. In both cases the balance between neurodestruction and neuroprotection appears modulated by the function of the adaptive immune system. MS is a chronic inflammatory disease of the central nervous system (CNS), leading to permanent disability. It seems certain that an autoimmune response directed against the CNS is central to the pathogenesis of the disease. While these CNS-specific T cells are activated in MS patients, they are inactive and naive in healthy. Therefore it is believed that an activation of autoreactive T cells by cross-reactivity with pathogens occurs outside of the CNS. In consequence T cells express adhesion molecules and proteinases which enable them to cross the blood-brain barrier. In stroke, however, the blood-brain barrier is disturbed in its integrity caused by the decreased blood flow. Cells can freely migrate from the periphery into the brain. CNS autoreactive cells from the periphery can be activated within the CNS and thus contribute to further tissue damage. While the local autoimmune response remains temporary in stroked brains, it is chronically destroyed in MS. The differences between the underlying mechanisms are not understood. This thesis investigated T cell responses in Multiple Sclerosis in response to the therapeutics Mitoxantrone and IFN-b. The induction of a TH1 to TH2 cytokine response appears to be a shared mechanism of action between both therapeutic agents. Primarily the post stroke immune response was investigated. Patients developed a stroke induced immune suppression characterized by monocytic dysfunction and lymphocytopenia explaining the high frequency of post stroke infections. Moreover early post stroke predictors of subsequent infections, like the CD4+ T cell count, were identified. The T cell response of stroke patients appeared primed to proinflammation and unsuppressed after mitogen stimulation. A detailed understanding of post stroke immune alterations may offer new avenues of intervention to improve the clinical fate of stroke victims. In addition, such knowledge could also further our understanding of Multiple Sclerosis, because, while increasing the infection risk, the dampening of the immune system could have an important protective function, if it limits autoimmune brain damage triggered by the massive release of brain antigens during stroke. If these two pathways could be modulated separately it would create the opportunity to develop distinct therapeutic approaches that inhibit autoimmunity and strengthen antibacterial defenses. To further delineate these mechanisms it is crucial to investigate the role of the innate immune system as compared to the adaptive immune system in stroke induced immune suppression.
Humanity is constantly confronted with the emergence and reemergence of infectious diseases. Many of them produce large or devastating epidemics, like AIDS (HIV) and Ebola. Others have been long neglected, yet pose immediate threats to global public health as evidences the abrupt emergence of Zika virus in South America and its association with microcephaly in babies. The examples illustrate, that many of these diseases are provoked by RNA viruses. One of the first steps in understanding and eliminating those threats is the development of sensitive and rapid diagnostic methods. A general and relatively rapid method is the direct detection and examination of the agent’s genome. However, the nature of (re)emerging RNA viruses poses a series of very specific problems for the design of such methods. Therefore, a systematic approach was proposed for the design of DNA-hybridization-base methods to detect and characterize RNA viruses that will have both a high sensitivity and a specificity sufficiently broad to detect, per reaction, down to a single copy of any of the possible variants of the viral genome.
Following this approach a series of assays were designed, developed or adapted and put into use for detection and characterization of important RNA viruses. One of those viruses is West Nile virus (WNV), which after its explosive introduction into USA become the most widespread flavivirus throughout the world and, consequently, many countries began an intensive monitoring. While existing assay detected predominantly the Lineage 1, in Europa Lineage 2 was expected. Two new RT-qPCR for the detection of both lineages were developed, and reportedly used by independent laboratories. Due to more than 50000 associated deaths per year, the Hepatitis E virus also received an increasing attention to elucidate novel routes of transmission. This virus (especially genotype 3) has the zoonotic potential of transmission from pigs and wild boar to humans. RT-qPCR and nested qPCR for detection and characterization of this virus as well as a methodology for subtyping were developed and the first detected case of subtype 3b in a German wild animal was documented. In addition a novel assay for flaviviruses conformed by a RT-qPCR coupled with a low density DNA microarray was developed, which enabled the identification of WNV in mosquitoes from Greece. A RT-qPCR suitable for surveillance and diagnostic of all known variants of Venezuelan equine encephalitis virus was developed too. A causative agent of hemorrhagic infections, the Ngari virus, was detected and characterized in animal samples from Mauritania. These achievements were supported by the development of software applications for selection and visualization of primers and probes from aligned DNA sequences and for modeling of DNA hybridizations using unaligned sequences.
In conclusion a general methodology for rapid development of sensitive diagnostic methods based in DNA-hybridization technics (PCR, sequencing and microarray) was stablished and successful applications are reported.
The present work is a paleolimnological orientated approach to refine and improve the indicator ability of freshwater ostracods from Holocene and Late glacial deposits in northeast Germany. The thesis follows two different approaches, one utilizes quantitative paleoenvironmental analysis, while the other evaluates ecological investigations of living specimens to extend the potential indicator group. For the first time quantitative ostracod analysis are carried out for a lacustrine basin (lake Krakower See) and a near-shore locality (Pudagla lowland) in the study area. The ecological investigation of living ostracods comprises 96 localities. The evaluation focused on environmental variables, which explain significantly the species composition. A canonical correspondence analysis identified at least four environmental parameters - water temperature, conductivity, pH-value, and mean water depth – which have an effect on ostracod assemblages. An extended analysis, which included only a subset of lake sites, revealed also that the former three environmental parameters affect the ostracod lake fauna, whereas the water temperature is the dominant factor. A temperature-transfer function could be regressed and calculated from the given trainingset by a weighted average model. These estimates can now be use in future paleolimnological investigations in northeast Germany to quantify the paleotemperature.
This dissertation explores and tries to unravel the fundamental basis of G-quadruplex end-folding as well as G-quadruplex interactions with small molecules by thermodynamic and structural approaches. Selective targeting of G-quadruplexes with ligands remains elusive, either because the ligand has
considerable binding affinity for other DNA structures or because it fails to discriminate between different G-quadruplex topologies. Unique structural motifs on the G-quadruplex may enhance or inhibit ligand binding to the G-quadruplex. For such aspects, it is necessary to understand the effect of G-quadruplex motifs or elements on the end-folding in order to better tune certain G-quadruplex topologies as model systems. Importantly for targeting G-quadruplex with ligands, motifs called Quadruplex-duplex (QD) junctions and interfaces are shown to be a binding hotspot
for various G-quadruplex ligands containing an intercalator motif. Binding affinity and selectivity of the ligands are discussed with the support of the NMR structures.
There is an increasingly urgent need to understand and predict how organisms will cope with the environmental consequences of global climate change. Adaptation in any form can be mediated by genetic adaptation and/or by phenotypic plasticity. Disentangling these two adaptive processes is critical in understanding and predicting adaptive responses to environmental change. Usually, disentangling genetic adaptation from phenotypic plasticity requires common garden experiments conducted under controlled laboratory conditions. While these experiments are powerful, it is often difficult to translate the results into natural populations and extrapolate to naturally occurring phenotypic variation. One solution to this problem is provided by the many examples of invasive species that exhibit wide phenotypic variation and that reproduce asexually. Besides selecting the appropriate in situ model, one must carefully choose a relevant trait to investigate. Ecomorphology has been a central theme in evolutionary biology because it reflects how organisms can adapt to their environment through their morphology. Intraspecific ecomorphological studies are especially well suited to identify adaptive pressures and provide insights into the microevolutionary mechanisms leading to the phenotypic differentiation.
One excellent candidate for an intraspecific ecomorphological study aiming to understand adaptation through genetic adaptation and phenotypic plasticity is the invasive New Zealand mudsnail Potamopyrgus antipodarum Gray (1853). This ovoviviparous snail features high variability in shell morphology and has successfully invaded a wide range of fresh- and brackish water habitats around the world. The evolutionary and ecological situations in this species’ native and invasive ranges is drastically different. In New Zealand, P. antipodarum’s native range, sexual and asexual individuals coexist and experience selective pressure by sterilizing endoparasites. By contrast, only a few asexual lineages have been established in invaded regions around the globe, where parasite infection is extremely rare. Here, we took advantage of the low genetic diversity among asexually reproducing European individuals in an attempt to characterize the relative contribution of genetic variation and phenotypic plasticity to the wide variation in shell morphology of this snail.
Analysing the ecomorphology of 425 European P. antipodarum in a geometric-morphometric framework, using brood size as proxy for fecundity, and mtDNA and nuclear SNPs to account for relatedness and identify reproductive mode, we hypothesized that 1) shell variation in the invasive range should be adaptive with respect to colonization of novel habitats, and 2) at least some of the variation might be caused by phenotypic plasticity. We then expanded our ecomorphological scope by analysing 996 native specimens, expecting 1) genetic and morphological diversity to be higher in the native range compared to invaded regions; 2) morphological diversity to be higher in sexual compared to asexual individuals according to the frozen niche hypothesis; and 3) shell morphology to be habitat specific, hence adaptative. In a last part, we used computational fluid dynamics simulations to calculate relative drag and lift forces of three shell morphologies (globular, intermediate, and slender). Here, we tested the overall hypothesis that shell morphology in gastropods is an adaptation against dislodgement through lift rather than drag forces, which would explain the counterintuitive presence of wider shells with shorter spires in lotic environments. With a final flow tank experiment, we tested the specific hypothesis that the dislocation velocity of living snails is positively linked to foot size, and that the latter can be predicted by shell morphology, in particular the aperture area as assumed by several authors.
As expected, we found genetic and morphological diversity to be higher in native than in invasive snails, but surprisingly no higher morphological diversity in sexual versus asexual individuals. The relationships between shell morphology, habitat, and fecundity were complex. Shape variation was primarily linked to genetic relatedness, but specific environmental factors including flow rate induced similar shell shapes. By contrast, shell size was largely explained by environmental factors. Fecundity was correlated with size, but showed trade-offs with shape in increasingly extreme conditions. With increasing flow and in smaller habitats such as springs, the trend of shell shape becoming wider was reversed, i.e. snails with slender shells were brooding more embryos. This increase in fitness was explained by our CFD simulations: in lotic habitats, slender shells experience less drag and lift forces compared to globular shells. We found no correlation between foot size and shell shape or aperture area showing that the assumed aperture/foot area correlation should be used with caution and cannot be generalized for all aquatic gastropod species. Finally, shell morphology and foot size were not related to dislodgement speed in our flow tank experiment. We concluded that the relationship of shell morphology and flow velocity is more complex than assumed. Hence, other traits must play a major role in decreasing dislodgement risk in stream gastropods, e.g. specific behaviours or pedal mucus stickiness. Although we did not find that globular shells are adaptations decreasing dislodgement risk, we cannot rule out that they are still flow related adaptations. For instance, globular shells are more crush-resistant and might therefore represent a flow adaptation in terms of diminishing damage caused by tumbling after dislodgement or against lotic specific crush-type predators.
At this point, we can conclude that shell morphology in P. antipodarum varies at least in part as an adaptation to specific environmental factors. This study shows how essential it is to reveal how plastic, genetically as well as phenotypically, adaptive traits in species can be and to identify the causal factors and how these adaptations affect the fitness in order to better predict how organisms will cope with changing environmental conditions.
Universal products provide an axiomatic framework to study noncommutative independences general enough to include, besides the well known "single-faced" case (i.e., tensor, free, Boolean, monotone and antimonotone independence), also more recent "multi-faced" examples like bifree independence. Questions concerning classification have been fully answered in the single-faced case, but are in general still open in the multi-faced case. In this thesis we discuss how one can use insights in the relation between universal products and their associated moment-cumulant formula as a starting point towards a combinatorial approach to (multi-faced) universal products. We define certain classes of partitions and discuss why the defining axioms are sufficient to associate to each of them a multi-faced universal product. For the two-faced case we present our result that every positive and symmetric universal product can be produced in this fashion and we outline how these results might contribute to a classification of positive and symmetric universal products.
The biodiversity of marine microorganisms opens a promising potential for the discovery of new technical enzymes. During this study a characterization of marine microorganisms, isolated from Arctic or Antarctic ice, sea water or sediment from the ocean was performed based on a comprehensive strain collection at the Alfred-Wegener-Institut für Polar- und Meeresforschung. These marine psychrophilic bacteria indicated a wide spectrum of extracellular cold-active enzymes. 16S rRNA sequencing revealed that many of these psychrophilic bacteria represent new species. Characterization of selected isolates by means of transmission electron or raster electron microscopy showed remarkably pleomorphic cellular structures throughout their growth. The major part of this thesis focuses on a marine Antarctic, psychrophilic bacterium (strain ANT/505) isolated from sea ice covered surface water from the Southern Ocean, which was identified to express a very uncommon enzymatic activity for the marine environment, namely a pectinolytic activity. The sequencing of the 16S rRNA of isolate ANT/505 and biochemical tests indicated a taxonomical affiliation to the specie Pseudoalteromonas haloplanktis. The supernatant of this bacterial isolate showed after growth on citrus pectin three different pectinolytic activities. By activity screening of a genomic DNA library of isolate ANT/505 in Escherichia coli, two different pectinolytic clones could be isolated. Subcloning and sequencing revealed two open reading frames of 1671 and 1968 nt corresponding to proteins of 68 and 75 kDa. The deduced amino acid sequence of the two orfs showed homology to pectate lyases from Erwinia chrysanthemi and Aspergillus nidulans. The pectate lyases contain signal peptides of 17 and 26 amino acids length that were correctly processed after overexpression in E. coli BL21. Both enzymes were purified by anionic exchange chromatography. Maximal enzymatic activities for both pectate lyases were observed at a temperature of 30°C and a pH range of 9-10. The Km values of both lyases for pectate and citrus pectin were 1 g⋅l-1 and 5 g⋅l-1, respectively. Calcium was required for activity on pectic substrates, while the addition of 1 mM ethylenediaminetetraacetic acid (EDTA) resulted in complete inhibition of the enzymes. These two cold-adapted enzymes represent the first pectate lyases isolated and characterized from a marine bacterium. Further cloning and sequence analyses revealed that PelA from P. haloplanktis is an exceptionally big bifunctional enzyme featuring pectate lyase and pectin methylesterase activity. The deduced amino acid sequence of the pectin methylesterase domain showed homology to group I pectin methylesterases from Erwinia chrysanthemi and Erwinia carotovora. The pectin methylesterase domain of PelA was found to show highest homology to a potential pectin methylesterase from Saccharophagus degradans strain MD2-40. Maximum pectin methylesterase activity of PelA was detected at a pH of 7.5 and a maximum temperature of 30°C. This cold-adapted enzyme revealed high remaining pectin methylesterase activity at low temperatures around 5°C and was quickly unstabilized at temperatures above 45°C. The analysis of the localization of the two pectinolytic genes on the genome of P. haloplanktis ANT/505 revelaed that these pectinase genes are expressed from independent cistrons, which are not clustered but located at distant positions on chromosome I of the P. haloplanktis genome. It was found that the transcription of both pectinase genes is induced by the presence of pectin. By means of primer extension the promoter regions of both cistrons were detected.
We all know the experience of different demands on ourselves. As a parent, we want to be there for our children, and in pursuit of our career, we want to invest as much time as possible. If we are committed to both being a good parent and pursuing a career, it may be impossible to satisfy the demands stemming from both commitments. It is in such moments in which our, what I call, practical identities are conflicted that our will is in a state of volitional disunity. In this dissertation, I discuss how a person may best cope with volitional disunity.
I define practical identities in line with Christine M. Korsgaard as self-descriptions under which a person finds her life worth living and her actions worth undertaking; examples of such self-descriptions are being a parent, an employee, a hobbyist pianist, the friend of Charlotte, etc. Practical identities provide the person with ideals that form a decision-making framework for her deliberations about what to do. The standard analysis of volitional disunity, is that it causes a person to not know what to do as her identities, as guides, point her in conflicting, even opposite, directions. The solutions proposed in the literature always include, what I call, the Unification Ideal: a person has to prioritize her identities by deciding which is more important to her. By unifying her identities in this way, she constitutes who she is and wants to be thereby providing herself with a clear decision-making framework regarding the question of what to do.
In this dissertation however, I argue that a person does not need to overcome her volitional disunity through unification per se. In order to know what to do, a person could also explore the disunity that defines her will, which includes that she could accept the volitional disunity as hers. I base this Exploration Ideal on two assumptions about human nature: 1) we have inner responses to how we act and 2) we are opaque to ourselves. Since a person cannot always know in advance whether she will be happy with a commitment by turning her attention inwards, she can explore who she wants to be and who she can be through the bodily, psychological, and emotive responses she has to her actions. These responses, however, are not the ultimate authority. This authority stays with her practical identities in light of which she can evaluate these inner responses. Thus, a person exposed to volitional disunity should strive to explore this disunity, how she wants it to define her and whether it is constitutive of who she is (Exploration Ideal) instead of trying to overcome the disunity by striving for unification (Unification Ideal).
Psychiatric disorders are highly heritable. But the underlying molecular mechanisms are largely unknown or not understood. For many disorders, candidate genes have been proposed which are biologically driven or based on large GWAS studies. In this work different approaches were shown to investigate the impact of genetic risk factors for major psychiatric disorders in the general population. These genetic risk variants include single nucleotide polymorphisms associated with schizophrenia or major depression and were analyzed using the whole-genome information in polygenic scores or candidate marker analysis in GxE studies. Genetic data from SHIP-0 and SHIP-TREND have been used to calculate a polygenic risk score for schizophrenia. Here, the association between this genetic score and brain alterations is shown in three independent samples (SHIP-2, SHIP-TREND and BIG) which revealed no hint of a common genetic basis for schizophrenia and brain structure. These results are in line with other studies that also failed to find a genetic overlap. The same polygenic scores had been used in a PHEWAS analysis in SHIP-0 where an inverse association to migraine was found. This association could be attributed to the NMDA receptor activation via D-serine at the glutamatergic synapse. To assess the impact of environmental factors on the path from genes to phenotype, gene-environment interactions were applied. A significant interaction could be observed between rs7305115 (TPH2) and rs25531 (5-HTTLPR) and childhood abuse on current depression score in SHIP-LEGEND and SHIP-TREND. In summary, genetic variants associated with major psychiatric disorders can exhibit pleiotropic effects on common phenotypes in the general population.
Herpesviruses are a fascinating group of enveloped DNA viruses, which rely on membrane fusion for infectious entry and direct cell-to-cell spread. Compared with many other enveloped viruses, they utilize a remarkably complex fusion machinery. Three conserved virion proteins, the bona fide fusion protein gB, and the presumably gB activating gH/gL heterodimer constitute the conserved core fusion machinery and are believed to drive membrane fusion in a cascade-like fashion. Activation of this cascade in most alphaherpesviruses is proposed to be triggered by binding of gD to specific host cell receptors. The molecular details of this fusion process, however, remain largely elusive. Yet, a detailed mechanistic knowledge of this process would be greatly beneficial for the development of efficient countermeasures against a variety of diseases. In this thesis, the functional relevance of individual components of the essential gH/gL complex of the alphaherpesvirus PrV has been assessed by two different approaches: by reversion analysis (paper II) and site-directed mutagenesis (papers III-V). In contrast to other herpesviruses, gL-deleted PrV is able to perform limited cell-to-cell spread, providing the unique opportunity to passage the entry-deficient virus in cell culture to select for PrV revertants capable of infecting cells gL-independently. This approach already resulted in an infectious gL-negative PrV mutant (PrV-ΔgLPass), in which the function of gL was compensated by formation of a gDgH hybrid protein. Here, the requirements for gL-independent infectivity of a second independent revertant (PrV-ΔgLPassB4.1), were analyzed. Sequencing of the genes encoding for gB, gH and gD, revealed mutations in each of them. By means of a robust infection-free, transfection-based cell-cell fusion assay (paper I), we identified two amino acid substitutions in the gL-binding domain I of gHB4.1 (L70P, W103R) as sufficient to compensate for lack of gL. Two mutations in gB (G672R, ΔK883) were found to enhance fusogenicity, probably by lowering the energy, required for gB refolding from pre- to postfusion conformation. Coexpression of gHB4.1 and gBB4.1 led to an excess fusion, which was completely suppressed by gDB4.1 in the fusion assays. This was surprising since PrV gD is normally not required for in vitro fusion or direct viral cell-to-cell spread, clearly separating this process from fusion during entry, for which PrV gD is essential. The fusion inhibiting effect of gDB4.1 could be attributed to a single point mutation resulting in an amino acid substitution within the ectodomain (A106V). In conclusion, these results indicated that gL is not central to the fusion process, as its function can be compensated for. As found so far, gL-independent infectivity can be realized by compensatory mutations in gH (as in PrV-ΔgLPass) or in gH plus gB (as in PrV-ΔgLPassB4.1). Excessive fusion induced by gHB4.1 and gBB4.1 was counter-regulated by gDB4.1, indicating that the interplay between these proteins is precisely regulated and further implies that gL and gD, despite being not absolutely essential for the fusion process, have important regulatory functions on gH and/or gB.
Both PrV-ΔgLPass mutants had acquired compensatory mutations in gH affecting the predicted gL-binding domain I in gH. By construction of an artificial gH32/98, which lacked the predicted gL-binding domain and was similar to the recently crystallized gH-core fragment present in the gDgH hybrid protein, we identified the N-terminal part of PrV gH as essential for gH function during fusion (paper III). gH32/98 was unable to promote fusion of wild-type gB in fusion assays and led to a total loss of function in the viral context. These results indicated that the gD moiety, present in gDgH, is critical for proper function of the gH-core fragment. We hypothesize that the gD moiety may adopt a stabilizing or modulating influence on the gH structure, which is normally executed by gL and important for interaction of gH with wild-type gB. Remarkably, substitution of wild-type gB by gBB4.1 rescued function of gH32/98 in the cellular and viral contexts. These findings suggest that gBB4.1 has been selected for interaction with “gL-less” gH. In conclusion, these results demonstrated that gL and the gL-binding domain are not strictly required for membrane fusion during virus entry and spread but that compensatory mutations must be present in gB to restore a fully functional fusion machinery. These results strongly support the notion of a functional gH-gB interaction as a prerequisite for membrane fusion.
In addition to the N-terminal domain, we identified the transmembrane domain of PrV gH as an essential component of the fusion machinery, while the cytoplasmic domain was demonstrated to play a modulatory but nonessential role (paper IV). Whereas truncation or substitution of the PrV gH TMD by a gpi-anchor or the analogous sequence from PrV gD rendered gH non-functional, the HSV-1 gH TMD was found to functionally substitute for the PrV gH TMD in cell-cell fusion and complementation assays. Since residues in the TMD which are conserved between HSV and PrV gH but absent in PrV gD, are placed on one face of an α-helical wheel plot, we hypothesize that the gH TMD has an intrinsic property to interact with membrane components such as lipids or other molecules as a requirement for promoting membrane fusion.
In a final study focusing on the function of gH, we identified the N-glycosylation sites utilized by PrV gH, and determined their individual role in viral infection (paper V). PrV gH was found to be modified by N-glycans at five potential glycosylation sites. N-glycans at PrV specific N77 and the highly conserved site N627 were found to be critical for efficient membrane fusion in the fusion assays, and during viral entry and cell-to-cell spread. N627 was further shown to be crucial for proper gH transport and maturation. In contrast, inactivation of N604, conserved in the Varicellovirus genus, enhanced in vitro fusion activity and viral cell-to-cell spread. These findings demonstrated a role of the N-glycans in proper localization and function of PrV gH.
Surface and electrode modifications allow the alteration of surface and electrode properties required for certain applications. In the first part of this thesis, a pH sensitive graphite/quinhydrone composite electrode for Flow-Injection-Analysis (FIA) systems was optimized by using polysiloxane as binder material. This allows an easier handling of the electrode. Furthermore, new applications of the FIA system in conjunction with the pH sensitive detection system were developed. The electrode used here in conjunction with a common reference electrode proved to be a very useful potentiometric detector for FIA acid-base titrations of aqueous solutions. Even acid-base titrations in buffered solutions were performed successfully with the FIA system allowing the determination of activities of enzymes, which catalyse reactions with increasing or decreasing proton concentrations. A FIA system was applied to measure calcium and magnesium ions in different water samples by measuring the hydronium ion release during the complexometric reaction between EDTA and calcium or magnesium ions. A method was established to determine sequentially the titratable acidity and the pH of different wine samples. The new FIA method fulfils the official requirements of the "Organisation Internationale de la Vigne et du Vin" with respect to reproducibility and repeatability and can be easily adjusted to the legal requirements in USA and Europe. In summary, the first part of this thesis shows that the FIA system in conjunction with the graphite/quinhydrone/polysiloxane composite electrode is very well suited for simple, rapid and automatic determinations of small sample volumes in the areas of water analysis, food analysis or even biochemical analysis, provided that hydronium ions are involved. For all applications, one and the same measuring device without changing the detection system is used. Only different carrier solutions are necessary, which can be provided by a proper stream selector. The second part of this thesis is focused on the modification of gold surfaces of medical devices by treatment with OH radicals. These investigations are based on previous studies of the impact of OH radicals on mechanically polished gold surfaces resulting in a smoothing of the surface by dissolution of highly reactive gold atoms. In this thesis, the effect of OH radicals, generated either ex vivo by Fenton solutions or in vivo by immune reactions, on gold implants was analysed using atomic force microscopy. It was found that there is an analogy between the exposure of gold to Fenton solutions and the exposure of gold to immune reactions. The pre-treatment of gold implants with OH radicals of Fenton solution prevents surface alterations of the gold implants in vivo. This indicates that the in vivo release of gold from implants can be reduced by exposing the gold implants to Fenton solution before implantation. Finally, the modification of gold surfaces by OH radicals was applied to a medical nanodetector, which is coated with a gold layer and functionalized with antibodies, for isolating circulating tumour cells (CTCs) from the blood stream of cancer patients. By treating the gold layer of the nanodetector with OH radicals generated by Fenton solution or by UV-photolysis of hydrogen peroxide, the cytotoxicity of the gold layer after gamma irradiation was reduced to almost zero. This modification of the gold surface with OH radicals allows applying the nanodetector for in vivo applications.
About 30 % of epileptic patients are non-responsive to multidrug antiepileptic therapy. One of non-responsiveness in epilepsy hypothesis claims that non-responsiveness occurs because of reduced access of antiepileptic drugs to their targets, as a result of increased efflux of antiepileptic drugs away from these targets. Transporters believed to be involved in non-responsiveness in epilepsy are mainly but not exclusively the members of the ABC superfamily including P-gp (MDR1, ABCB1), MRP1 (ABCC1), MRP2 (ABCC2) and others. These proteins are normally found in the blood-brain barrier and the blood-cerebrospinal fluid barrier where they function as protectors. There is emerging evidence that P-gp, MRP1 and MRP2 are up-regulated in epileptogenic brain tissue. The risk of non-responsiveness could be related also to the MDR1 or MRP2 gene polymorphisms. We hypothesised that changes in expression and function of multidrug transporters involved in non-responsiveness of epilepsy might be detectable not only in the brain but also in other tissues such as lymphocytes. Therefore we evaluated the expression of MDR1, MRP1 and MRP2 and function of P-gp in lymphocytes in patients with epilepsy and healthy subjects. Three groups of epileptic patients and 15 healthy subjects as a control group were included in the study. The patients’ group was defined as follows: Monotherapy – patients treated with carbamazepine monotherapy, without seizures - corresponded to group responders. Combined therapy – patients after monotherapy (two different medicines have been tried) and combined therapy (two trials of combined therapy), not free of seizures. Monotherapy and combined therapy groups each embraced 15 patients. Neurosurgery – patients who had undergone neurosurgery, afterwards were or were not additionally treated with carbamazepine, with or without seizures. This group comprised 24 patients. Combined therapy and neurosurgery groups composed the group of non-responders. The mRNA expression of MRP1, MRP2 and MDR1 by means of quantitative real-time PCR as well as MRP2 and P-gp protein content by Western blot in lymphocytes was measured. For P-gp functional analysis rhodamine efflux from lymphocytes and natural killer (NK) cells was performed. The influence of the polymorphisms C3435T, G2677T/A in the MDR1 gene and C24T, G1249A, C3972T in the MRP2 gene for the transporters expression, function and their association with non-responsive epilepsy phenotype was investigated. Our results showed that MRP1 expression in lymphocytes was significantly lower in epileptics than in healthy subjects. Non-responders had lower MRP1 mRNA content in lymphocytes than responders. We did not find any difference in MRP2 expression between epileptics and healthy volunteers. MRP2 mRNA levels in lymphocytes were higher in non-responders than in responders. However, at protein level epileptic patients had significantly lower MRP2 content in lymphocytes than controls. MRP2 protein content did not differ in responders and non-responders. There was no reliable correlation between MRP2 mRNA expression and MRP2 protein content in lymphocytes. Epileptics had significantly lower MDR1 expression in lymphocytes than healthy individuals. MDR1 expression was decreasing according to the consumption of antiepileptic drugs and seizures frequency: patients after neurosurgery had significantly lower MDR1 expression than patients after combined therapy and monotherapy. MDR1 expression was significantly lower in non-responders than in responders. At protein level epileptics had lower P-gp content than controls. Detected P-gp amount in lymphocytes did not differ between responders and non-responders. Rhodamine efflux from lymphocytes and NK cells did not differ significantly between epileptics and healthy subjects, but it was higher in patients after neurosurgery than in patients after monotherapy. Rhodamine efflux from NK cells, which are known to express the highest levels of P-gp, was significantly higher in non-responders than in responders. In this study, we showed that MRP1 mRNA expression in lymphocytes was significantly correlated to its expression in the brain. We detected also a significant co-correlation between MRP1 expression in the hippocampus and MDR1 expression in lymphocytes. We found no evidence regarding the impact of the MDR1 polymorphisms on mRNA expression, P-gp content and rhodamine efflux from lymphocytes. Our data showed lack of evidence regarding the impact of the MRP2 polymorphisms on mRNA expression and protein content. We did not detect any association between MDR1 or MRP2 polymorphisms and non-responsiveness in epilepsy or epilepsy in the main. In conclusion, our results suggest that lymphocytes are an appropriate surrogate for studies on changes of multidrug transporters expression in epilepsy. Lymphocytes as an easily accessible tissue might serve as a marker for responsiveness to antiepileptic drug therapy in epilepsy studies.
Summary Prostate cancer (PCa) is the most common type of cancer found in men from western countries and is the leading cancer death next to lung cancer and colorectal cancer. Proteomic studies on PCa identified a number of differentially expressed proteins and some of them were reported as potential markers, but clinical application of these markers is mostly missing. Most of the expression profiling studies have been carried out on radical prostatectomy specimens, formalin-fixed paraffin-embedded (FFPE) tissue sections, serum, urine and prostate fluids. To define the protein expression pattern of prostate biopsies, in the present study we investigated biopsy samples from benign prostate hyperplasia (BPH) and PCa patients by two-dimensional gel electrophoresis (BPH n=11 and PCa n=12) and mass spectrometry to identify potential biomarkers which might distinguish the two clinical situations. 2-DE results revealed 88 protein spots expressed differentially among hyperplasia and cancer groups with statistical significance. Interesting spots were analyzed by MALDI-TOF-MS-MS and 79 different proteins identified. The important proteins identified included, Prohibitin and NDRG1 tumor suppressor proteins, HSPs, cytoskeletal proteins, enzymes like DDAH1 and ALDH2. Prohibitin expression was investigated in detail at mRNA level and protein level using immunohistochemistry on prostatectomized specimens. We found that the level of mRNA for prohibitin correlates with the increased amount of protein indicating the involvement of changes at transcriptional level. Furthermore, immunohistochemistry revealed no staining in BPH, moderate staining in prostate intraepithelial neoplasia (PIN) and strong staining in PCa. From the list of differentially proteins compared to PCa, TPD52 is over expressed in prostate cancer and also mRNA estimation by real-time PCR confirmed over expression of TPD52 at transcriptional level in cancer. TPD52 is a protein over expressed in prostate and breast cancer due to gene amplification but its exact physiological function is not investigated in detail. In the present study, we explored the responsiveness of LNCaP cells after dysregulation of TPD52 expression. Transfection of LNCaP cells with specific shRNA giving efficient knockdown of TPD52 resulted in a significant cell death of the carcinoma LNCaP cells. As evidenced by the activation of caspases (caspase-3 and -9) and by the loss of mitochondrial membrane potential, cell death occurs due to apoptosis. The disruption of the mitochondrial membrane potential indicates that TPD52 acts upstream of the mitochondrial apoptotic reaction. To study the effect of TPD52 expression on cell proliferation, LNCaP cells were either transfected with EGFP-TPD52 or a specific shRNA. EGFP-TPD52 overexpressing cells showed an increased proliferation rate whereas TPD52-depleted cells showed a reverse effect. Additionally, we demonstrated that the exogenous expression of TPD52 promotes cell migration via ávâ3 integrin in prostate cancer cells through the activation of protein kinase B (PKB/Akt) pathway. In an attempt to identify new interacting proteins for TPD52, GST pulldown assays provided evidence for the physical interaction between TPD52 and Prx1 in LNCaP cells. Further, immunoprecipitation results confirmed this interaction. Our results demonstrates that protein profiling and mRNA studies can be performed on prostate biopsies. Moreover, our study revealed a significant up-regulation of prohibitin in prostate cancer compared to BPH which may be a potential marker to distinguish PCa and BPH. From the results for functional characterization of TPD52, we conclude that TPD52 plays an important role in various molecular events particularly in morphological diversification and dissemination of PCa. It may be a promising target to investigate further in detail to develop new therapeutic strategies to treat PCa patients. Caspases represent a family of cysteine proteases that are regarded as central executioners of apoptotic cell death. Activation of caspase cascade is an essential prerequisite in the induction of apoptosis in cellular systems. So far, in many tumors caspases were shown to be downregulated while anti-apoptotic Bcl-2 is up-regulated. To get insight in their putative role in PCa progression we determined the expression of caspase-1, uncleaved caspases 3 and 6, cleaved (activated) caspases 3 and 6, caspase-9 and antiapoptotic protein Bcl-2 in benign prostate epithelium (BPE) and prostate carcinoma. In the current study 20 prostates were obtained from patients undergoing radical prostatectomy due to PCa. Paraffin embedded prostate whole mounts were cut at (4 µm) and investigated immunohistochemically using anti-mouse monoclonal antibodies directed against caspases 1 and 9, uncleaved caspases 3 and 6, cleaved caspases 3 and 6, and Bcl-2. In BPE all caspases were localized in the cytoplasm of glandular cells. Comparing BPE to PCa, no differences were found for caspase-1, uncleaved caspases 3 and 6 as well as caspase-9. Immunostaining for cleaved caspases 3 and 6, however, revealed a statistically significant reduction in PCa compared to non-neoplastic tissue. Whereas in BPE Bcl-2 protein was detected in the basal compartment of epithelial gland cells no immunostaining was seen in PCa. As our results show a decreased amount of activated caspases may be due to the alterations of posttranslational cleavage rather than expression of caspases 3 and 6. This suggests that the modification in their activation pathway could play an important role during PCa progression.
The history of Mathematics has been lead in part by the desire for generalization: once an object was given and had been understood, there was the desire to find a more general version of it, to fit it into a broader framework. Noncommutative Mathematics fits into this description, as its interests are objects analoguous to vector spaces, or probability spaces, etc., but without the commonsense interpretation that those latter objects possess. Indeed, a space can be described by its points, but also and equivalently, by the set of functions on this space. This set is actually a commutative algebra, sometimes equipped with some more structure: *-algebra, C*-algebra, von Neumann algebras, Hopf algebras, etc. The idea that lies at the basis of noncommutative Mathematics is to replace such algebras by algebras that are not necessarily commutative any more and to interpret them as "algebras of functions on noncommutative spaces". Of course, these spaces do not exist independently from their defining algebras, but facts show that a lot of the results holding in (classical) probability or (classical) group theory can be extended to their noncommutative counterparts, or find therein powerful analogues. The extensions of group theory into the realm of noncommutative Mathematics has long been studied and has yielded the various quantum groups. The easiest version of them, the compact quantum groups, consist of C*-algebras equipped with a *-homomorphism &Delta with values in the tensor product of the algebra with itself and verifying some coassociativity condition. It is also required that the compact quantum group verifies what is known as quantum cancellation property. It can be shown that (classical) compact groups are indeed a particular case of compact quantum groups. The area of compact quantum groups, and of quantum groups at large, is a fruitful area of research. Nevertheless, another generalization of group theory could be envisioned, namely by taking a comultiplication &Delta taking values not in the tensor product but rather in the free product (in the category of unital *-algebras). This leads to the theory of dual groups in the sense of Voiculescu, also called H-algebras by Zhang. These objects have not been so thoroughly studied as their quantum counterparts. It is true that they are not so flexible and that we therefore do not know many examples of them and showing that some relations cannot exist in the dual group case because they do not pass the coproduct. Nevertheless, I have been interested during a great part of my PhD work by these objects and I have made some progress towards their understanding, especially regarding quantum Lévy processes defined on them and Haar states.
Electromagnetic Drift Waves
(2010)
In the rf-plasma of the linear magnetized VINETA experiment, different types of low-frequency waves are observed. The emphasis in this work is on the interaction mechanism between drift waves on the one and kinetic Alfven waves on the other hand. In the peaked density profile of the plasma column drift waves occur as modulation of the plasma density. As gradient driven instability, they draw their energy from the radial density gradients. Alfven waves as magnetic field fluctuations are stable in the present configuration. They are launched by a magnetic excitation antenna. Parallel conduction currents in the plasma are common to both wave phenoma. A B-dot probe as standard diagnostic tool is used to detect the fluctuating magnetic fields of both wave types. The challenge are the small induced voltages due to the low wave frequency. The probe design with an integrated amplifier close to the probe head takes this into acount. The developed B-dot probe is mounted to different positioning systems to characterize both wave phenomena. For Alfven waves, the dispersion relation is recorded experimentally. It is found to be in good agreement with the prediction of the Hall-MHD theory with included resistive term, accounting for the cold collisional plasma. The fluctuating magnetic field pattern is recorded with azimuthal scans. The current density is obained by Amperes law. It is concentrated in helically twisted current filaments. For the unstable drift waves, similar investigations are done with simultaneously recorded density fluctuations. In the azimuthal plane, the locations of the parallel current filaments and the fluctuating density are found to be in phase, supporting the predicted drive of parallel currents by pressure gradients. A mutual influence of the two wave types is observed in an interaction experiment. Assuming parallel currents as coupling quantity, an interpretation of the experimental findings is given based on the linear theory of drift waves.
Background: Sedentary behavior (SB) is a modifiable behavior with increasing prevalence worldwide. There is emerging evidence that time spend in SB and the manner in which SB is accumulated over time is associated with cardiovascular and cardiometabolic health. The requirement for SB data to be accurately measured is minimization, or at least accurate quantification of human-related sources of measurement errors such as accelerometer measurement reactivity (AMR). The present thesis was to examine SB and their associations with cardiovascular and cardiometabolic health, and to focus on challenges related to the assessment of SB. The first aim of the thesis was to identify patterns of SB describing how individuals accumulate their time spend in SB day-by-day over one week, and to examine how these patterns are associated with cardiorespiratory fitness as a marker for cardiovascular health (paper 1). The second aim of the thesis was to examine the multiple types of SB, and how this is associated with a clustered cardiometabolic risk score (CMRS; paper 2). The third aim of the thesis was to examine AMR and the reproducibility in SB and physical activity (PA) in two measurement periods, and to quantify AMR as a confounder for the estimation of the reproducibility of SB and PA data (paper 3).
Methods: The three papers were based on data of two different studies. For study 1, 1165 individuals aged 40 to 75 years were recruited in three different settings. Among these, 582 participated in a cardiovascular risk factor screening program including cardiopulmonary exercise testing. For the analyses of paper 1, 170 participants were eligible, agreed to wear an accelerometer, fulfilled the wearing regime, and completed the study period by wearing the accelerometer for seven consecutive days. Patterns in accelerometer data were classified based on time spent in SB per day applying growth mixture modeling. Model‐implied class‐specific peak oxygen uptake (VO2peak) means were compared using adjusted equality test of means (paper 1). The underlying study of paper 2 and 3 were based on data of a pilot study aiming to investigate the feasibility of a brief tailored letter intervention to increase PA and to reduce SB during leisure time. Among the individuals who agreed to be contacted again in study 1, a random sample of those aged between 40 and 65 years was drawn. Of those, 175 attended in a cardiovascular examination program. Assessment included giving blood sample, standardized measurement of blood pressure, waist circumference, body weight, and height at baseline, and after twelve months. Further, they agreed to complete a paper-pencil questionnaire on SB (Last 7-d Sedentary Behavior Questionnaire, SIT-Q-7d) and PA (International Physical Activity Questionnaire, IPAQ), and to receive seven-day accelerometery at baseline, and after 12 months. In addition, self-administered assessments were conducted at months one, three, four, and six after baseline. Only individuals of a random subsample (= intervention group) received up to three letters tailored to their self-reported SB and PA at months one, three, and four. For paper 2, associations between SBs and a clustered cardiometabolic risk score (CMRS) were analyzed using linear as well as quantile regression. To account for missing values at baseline, multiple imputations using chained equations were performed resulting in a total sample of 173 participants. Paper 3 comprised data of 136 individuals who participated at the baseline and twelve months assessments, and fulfilled the wearing regime. AMR was examined using latent growth modeling in each measurement period. Intraclass correlations (ICC) were calculated to examine the reproducibility of SB and PA data using two-level mixed-effects linear regression analyses.
Results: Results of paper 1 revealed four patterns of SB: 'High, stable', 'Low, increase', 'Low, decrease', and 'High, decrease'. Persons in the class 'High, stable' had significantly lower VO2peak values (M = 25.0 mL/kg/min, SD = 0.6) compared to persons in the class 'Low, increase' (M = 30.5 mL/kg/min, SD = 3.6; p = 0.001), in the class 'Low, decrease' (M = 30.1 mL/kg/min, SD = 5.0; p = 0.009), and in the class High, decrease' (M = 29.6 mL/kg/min, SD = 5.9; p = 0.032), respectively. No differences among the other classes were found. In paper 2, results revealed that the only factor positively associated with a CMRS in all regression models was watching television. Depending on the regression analysis approach used, other leisure-time SBs showed inconsistent (using a computer), or no associations (reading and socializing) with a CMRS. In paper 3, results revealed that time spent in SB increased (baseline: b = 2.3 min/d; after 12 months: b = 3.8 min/d), and time spent in light PA decreased (b = 2.0 min/day; b = 3.3 min/d). However, moderate-to-vigorous PA remained unchanged. Accelerometer wear time was reduced (b = 4.6 min/d) only at baseline. The ICC coefficients ranged from 0.42 (95% CI = 0.29 - 0.57) for accelerometer wear time to 0.70 (95% CI = 0.61 - 0.78) for moderate-to-vigorous PA. None of the regression models identified a reactivity indicator as a confounder for the reproducibility of SB and PA data.
Conclusions: The present thesis highlights SB in the field of cardiovascular and cardiometabolic research that have implications for future research. Individuals sit for different purposes and durations in multiple life domains, and the time spent in SB is accumulated in different patterns over time. Therefore, research should consider the fact that SB is embedded in an individual's daily life routine, hence might have differential effects on cardiovascular and cardiometabolic health. Further, methodological aspects have to be considered when dealing with SB. In order to detect how SB is 'independently' associated to an individual's health, an accurate measurement of SB is fundamental. Therefore, human-related sources of bias such as AMR should be taken into account when either planning studies or when interpreting data drawn from analysis of SB data.
1,1-Bis(trimethylsilyloxy)ketene acetals represent useful synthetic building blocks which can be regarded as masked carboxylic acid dianions. In recent years, a number of cyclization reactions of 1,1-bis(trimethylsilyloxy)ketene acetals have been reported. Functionalized maleic anhydrides represent important synthetic building blocks, which have been employed, for example, in the synthesis of γ-alkylidenebutenolides, maleimides, 5-alkylidene-5H-pyrrol-2-ones. Substituted maleic anhydrides are available by Michael reaction of nucleophiles with parent maleic anhydride and subsequent halogenation and elimination. Oxalyl chloride is an important synthetic tool for the synthesis of O-heterocycles. 3-hydroxymaleic (1-3) anhydrides were synthesised by one-pot cyclization of 1,1-bis(trimethylsilyloxy)ketene acetals with oxalyl chloride using TMSOTf as a catalyst. The Me3SiOTf mediated reaction of 1,1-bis(trimethylsilyloxy)ketene acetals with 3-silyloxyalk-2-en-1-ones, such as (4), afforded 5-ketoacids, such as (5). Treatment of the latter with TFA in CH2Cl2 afforded pyran-2-ones, such as (6-8). It has been found that 1,1-bis(trimethylsilyloxy)ketene acetals can behave as dinucleophile. Functionalized benzo-azoxabicyclo[3.3.1]nonanones (9-12), were prepared by regio- and diastereoselective condensation of 1,1-bis(silyloxy)ketene acetals with isoquinolinium and quinolinium salts and subsequent regioselective and stereospecific iodolactonization. Our next target was the reaction of silyl ketene acetals with pyrazine and quinoxaline. These reactions provide a facile access to a variety of 2,3-benzo-1,4-diaza-7-oxabicyclo[4.3.0]non-2-en-6-ones and 1,4-diaza-7-oxabicyclo[4.3.0]non-2-en-6-ones (13-14). The second part of my research work was concentrated on bis(silyl enol ethers). The TiCl4-mediated [3+3] cyclization of 2,4-bis(trimethylsilyloxy)penta-1,3-diene with 3-silyloxyalk-2-en-1-ones afforded 2-acetylphenols (15), which were transformed into functionalized chromones (16). The Me3SiOTf-mediated condensation of the latter with 1,3-bis(silyl enol ethers) and subsequent domino ′retro-Michael–aldol–lactonization′ reaction afforded 7-hydroxy-6H-benzo[c]chromen-6-ones (17-18). With regard to our on going investigation with bis(silyl enol ethers), we significantly extended the preparative scope of the methodology. We have successfully developed regioselective cyclizations of unsymmetrical 1,1-diacylcyclopentanes, such as 1-acetyl-1-formylcyclopentane, and also studied cyclizations of 2,2-diacetylindane, 1,1-diacetylcyclopent-3-ene and 3,3-dimethylpentane-2,4-dione. In addition, the mechanism of the domino process was studied. We have synthesised spiro[5.4]decenones (19) and that were transfored into bicyclo[4.4.0]deca-1,4-dien-3-ones (20-21), by domino ′Elimination–Double-Wagner-Meerwein-Rearrangement′ reactions. The Lewis acid mediated domino ′[3+3]-cyclization-homo-Michael′ reaction of 1,3-bis-silyl enol ethers with unsymmetrical 1,1-diacylcyclopentanes, such as 1-acetyl-1-formylcyclopentane, allows an efficient one-pot synthesis of functionalized salicylates containing a halogenated side-chain (22-23). A great variety of substitution patterns have been realized by variation of the starting materials and of the Lewis acid. The mechanism of the domino process was studied.
During infections, innate immune cells are crucial for initiating a pro-inflammatory immune response and clearing the invading pathogen. Delay in pathogen clearance or initiation of an immune response due to impaired functionality of immune cells can result in devastating consequences. The cellular compartment of the innate immune system comprises an array of specialized cell types: Macrophages are tissue-resident professional phagocytes that clear cellular debris, pathogens, and foreign objects. Dendritic cells (DCs) are immune sentinels specialized in antigen uptake and subsequent T cell priming. They are primary sources of cytokines in response to infection. Neutrophils are efficient effector cells that respond rapidly to infection and clear bacteria by different mechanisms. If effector mechanisms of these cells are affected by either bacterial or other factors, infections might not be resolved and can spread throughout the host. Cobalt-chromium-molybdenum biomaterial is widely used in arthroplasty. Implant-derived wear particles and ions lead to macrophage-driven adverse local tissue reactions: Such reactions have been linked to an increased risk of periprosthetic joint infection after revision arthroplasty. While metal-induced cytotoxicity is well characterized in human macrophages, direct effects on their functionality remain elusive. In Paper I, we show that local peri-implant tissue is exposed to Co and Cr in situ. Influx of macrophages is also evident. Exposure of isolated human monocytes/macrophages to Cr3+ in vitro had only minor effects. However, exposure of monocytes/macrophages to pathologic concentrations of Co2+ significantly impaired both phenotype and functionality. High concentrations of Co2+ induced loss of surface markers, including CD14 and CD16. Both Co2+ and Cr3+ impaired macrophage responses to Staphylococcus aureus infection. Co2+ -exposed macrophages, in particular, showed decreased phagocytic activity. These findings demonstrate the immunosuppressive effects of locally elevated metal ions on the innate immune response. Streptococcus pyogenes (group A streptococcus, GAS) causes a variety of diseases ranging from mild to severe necrotizing soft tissue infections (NSTIs). In the host environment hypervirulent GAS variants carrying mutations within the genes encoding for control of virulence (Cov)R/S two component system are enriched. This adaptation is associated with loss of SpeB secretion. In Paper II, we show that in vitro infections with hyper-virulent GAS variants harboring dysfunctional CovR/S suppress secretion of IL-8 and IL-18 by human monocytic cells. This phenotype was mediated by a caspase-8 dependent mechanism. Knockout of streptococcal SLO in a GAS strain carrying functional CovR/S even increased secretion of IL1β and IL-18 by moDCs. Of 67 fully sequenced GAS NSTI isolates, 28 contained covS or covR mutations that rendered the TCS dysfunctional. However, no differences in systemic IL-8 and IL-18 were detected in these patients. GAS isolates recovered from patients often display a mixed phenotype, consisting of SpeB positive (SpeB+ ) and SpeB negative (SpeB- ) clones. Irreversible loss of SpeB expression is often caused by loss of function mutations in regulatory components (CovR/S, RopB). Loss of SpeB is often associated with hyper-virulence. In Paper III, we show that the host environment induces transiently abrogated secretion of SpeB by GAS. Tissue inflammation, neutrophil influx, and degranulation correlated with increased frequencies of SpeB- GAS clones. Isolates recovered from tissue expressed but did not secrete SpeB, which was reversible. Neutrophilderived ROS were identified as the main factor responsible for abrogated SpeB secretion. Hyper-virulent SpeB- clones also exhibit better survival within and induce excessive degranulation of neutrophils.
Methane (CH4) is a potent greenhouse gas with rising atmospheric concentrations.
Microorganisms are essential players in the global methane cycle. In fact, the largest part of methane emissions derives from microbial production by methanogenic Archaea (methanogens). Microorganisms do not only produce methane: methanotrophs can also oxidize the methane produced by methanogens. In addition, soil methanotrophs are the only biological methane sink, oxidizing up to 30-40 Tg of this potent greenhouse gas per year worldwide.
However, intensified management of grasslands and forests may reduce the methane sink capacity of soils.
In general, the interaction of methanogens and methanotrophs determines whether a soil is a source or a sink for methane. It is, therefore, crucial to understand the microbial part of the methane cycle and which factors influence the abundance and activity of methane-cycling microbes. However, capturing the soil microbiome's abundances, activity, and identity is
challenging. There are numerous target molecules and myriad methods, each with certain
limitations. Linking microbial markers to methane fluxes is therefore challenging. This thesis aimed to understand how methane-cycling microbes in the soil are related to soil methane fluxes and how soil characteristics and human activity influence them.
The first publication investigated the biotic and abiotic drivers of the atmospheric methane sink of soils. It assessed the influence of grassland land-use intensity (150 sites) and forest management type (149 sites) on potential atmospheric methane oxidation rates (PMORs) and the abundance and diversity of CH4-oxidizing bacteria (MOB) with qPCR in topsoils of three temperate regions in Germany. PMORs measured in microcosms under defined conditions were approximately twice as high in forest than in grassland soils. High land-use intensity of grasslands negatively affected PMORs (−40%) in almost all regions. Among the different aspects of land-use intensity, fertilization had the most adverse effect reducing PMORs by 20%.
In contrast, forest management did not affect PMORs in forest soils. Upland soil cluster (USC)α was the dominant group of MOBs in the forests. In contrast, USCγ was absent in more than half of the forest soils but present in almost all grassland soils. USCα abundance had a direct positive effect on PMOR in forests, while in grasslands, USCα and USCγ abundance affected PMOR positively with a more pronounced contribution of USCγ than USCα.
In the second publication, we used quantitative metatranscriptomics to link methane-cycling microbiomes to net surface methane fluxes throughout a year in two grassland soils. Methane fluxes were highly dynamic: both soils were net methane sources in autumn and winter and net methane sinks in spring and summer. Correspondingly, methanogen mRNA abundances per
gram soil correlated well with methane fluxes. Methanotroph to methanogen mRNA ratios were higher in spring and summer when the soils acted as net methane sinks. Furthermore, methane uptake was associated with an increased proportion of USCα and γ pmoA and pmoA2 transcripts. High methanotroph to methanogen ratios would indicate methane sink properties.
Our study links the seasonal transcriptional dynamics of methane-cycling soil microbiomes for the first time to gas fluxes in situ. It suggests mRNA transcript abundances as promising indicators of dynamic ecosystem-level processes.
We conclude that reduction in grassland land-use intensity and afforestation can potentially increase the methane sink function of soils and that different parameters determine the microbial methane sink in forest and grassland soils. Furthermore, this thesis suggests mRNA transcript abundances as promising indicators of dynamic ecosystem-level processes. Methanogen transcript abundance may be used as a proxy for changes in net surface methane emissions from grassland soils.
This thesis deals with the process considerations and optimizations of a whole-cell enzyme cascade reaction for the synthesis of ɛ-caprolactone. The enzyme cascade synthesis of ɛ-caprolactone has been conceptualized and verified using a dehydrogenase and a monooxygenase. The advantage of this enzyme combination is the closed-loop co-factor regeneration. Dehydrogenase and monooxygenase expressed in discrete whole cells were applied in defined ratio to conceptualize the cascade reaction. This necessitates the use of separate co-factor regeneration system due to impermeability of the E. coli cell wall to the co-factor. Article I deal with the design and optimization of dehydrogenase and monooxygenase co-expression in a same E. coli cell. In Article II, the cascade reaction was upscaled and a fed-batch process was realized. Following which, the important reaction metrices were analyzed and optimized. Article III extends the two-enzyme cascade with a lipase. The use of lipase helps to overcome the product inhibition of monooxygenase by ɛ-caprolactone.
Although the outcome of patients with acute myeloid leukemia (AML) has
improved in the past decades, the overall survival is below 50% [1, 2] and there
is still an unmet need for the development of new therapeutic strategies. Here,
we aimed to identify functional vulnerabilities in AML and investigated the
therapeutic potential of target structures involved in proteostasis, cell polarity and
RNA-binding molecular pathways.
We determined that genetic deletion of the cell fate determinant and polarity
regulator Scribble delays AML development, however, its deletion also seems to
affect the proliferative capacity of normal hematopoietic cells, lowering its value
as a therapeutic target. In contrast, inactivation of YBX1 (a pleiotropic protein with
DNA/RNA binding capacity that excerpts post-transcriptional control on its
targets) and PSMB8/LMP7 (a catalytic subunit of the immunoproteasome multiprotein
complex that belongs to the ubiquitin-proteasome system (UPS)) inhibit
leukemic cells without influencing normal hematopoietic stem and progenitor cell
function, establishing these targets as potential novel therapeutic strategies
against AML.
Genetic deletion of YBX1 caused reduced proliferation and colony forming
capacity in leukemic cells independent of the oncogenic driver mutation and
delayed AML development in vivo. The role of Ybx1 in leukemia maintenance
was investigated using a conditional knockout model, confirming the functional
requirement of Ybx1 in AML maintenance. Mechanistically, YBX1 recruited
oncogenic transcripts to polysomes, increasing their translation. Displacement of
these transcripts from polysomes after YBX1 deletion decreased their protein
expression.
Genetic and pharmacologic inhibition of PSMB8/LMP7 decreased proliferation
and colony forming capacity selectively in KMT2A (MLL)-rearranged leukemic
cells. In vivo treatment with a PSMB8/LMP7 inhibitor delayed disease
development in KMT2A-rearranged leukemic mice or patient derived xenografts
(PDX). We identified the transcriptional corepressor BASP1 as a functional
effector of the immunoproteasome. BASP1 was enriched after PSMB8/LMP7
inhibition and it was found binding to KMT2A-target genes. Moreover,
pharmacologic inhibition of PSMB8/LMP7 led to decreased expression of bonafide
KMT2A-fusion target genes and enrichment for genes deregulated by
inhibitors of the KMT2A complex partners DOT1L and MEN1. This prompted us
to investigate a potential synergism between MEN1 inhibition and
immunoproteasome inhibition. Combination treatment in AML cells revealed
decreased proliferation in vitro and increased survival in vivo as compared to the
single treatments, demonstrating the therapeutic potential of combining
immunoproteasome and MEN1 inhibitors.
This thesis highlights the impact of surface charges and negative ions on the pre-ionization, breakdown mechanism, and lateral structure of dielectric barrier discharges operated in binary mixtures of helium with nitrogen or electronegative oxygen. Sophisticated diagnostic methods, e.g., non-invasive optical emission spectroscopy and the electro-optic Pockels effect as well as invasive laser photodetachment and laser photodesorption, were applied at one plane-parallel discharge configuration to investigate both relevant volume and surface processes. Moreover, the experimental findings were supported by numerical fluid simulations of the discharge. For the first time, the memory effect of the measured surface charge distribution was quantified and its impact on the local self-stabilization of discharge filaments was pointed out. As well, it turned out that a few additional seed electrons, either desorbed from the charged dielectric surface or detached from negative ions in the volume, significantly contribute to the pre-ionization resulting in a reduced voltage necessary for discharge breakdown. Finally, effective secondary electron emission coefficients of different dielectrics were estimated from the measured breakdown voltage using an analytical model.
Individual white spruce (Picea glauca (Moench) Voss) growth limitations at treelines in Alaska
(2018)
White spruce (Picea glauca (Moench) Voss) is one of the most common conifers in Alaska and various treelines mark the species distribution range. Because treelines positions are driven by climate and because climate change is estimated to be strongest in northern latitudes, treeline shifts appear likely. However, species range shifts depend on various species parameters, probably most importantly on phenotypic plasticity, genetic adaptation
and dispersal. Due to their long generation cycles and their immobility, trees evolved to endure a wide variety of climatic conditions. In most locations, interannual climate variability is larger than the expected climate change until 2100. Thus treeline position is typically thought of as the integrated effect of multiple years and to lag behind gradual climate change by several decades. Past dendrochronological studies revealed that growth of white spruce in Alaska can be limited by several climatic variables, in particular water stress and low temperatures. Depending on how the intensity of climate warming, this could result in a leading range edge at treelines limited by low temperatures and trailing treelines where soil moisture is or becomes most limiting. Climate-growth correlations are the dendrochronological version of reaction norms and describe the relationship between an environmental variable and traits like tree-ring parameters (e.g. ring width, wood density, wood anatomy). These correlations can be used to explore potential effects of climate change on a target species. However, it is known that individuals differ with respect to multiple variables like size, age, microsite conditions, competition status or their genome. Such individual differences could be important because they can modulate climate-growth relationships and consequently also range shifts and growth trends. Removing individual differences by averaging tree-ring parameters of many individuals into site chronologies could be an oversimplification that might bias estimates of future white spruce performance. Population dynamics that emerge from the interactions of individuals (e.g. competition) and the range of reactions to the same environmental drivers can only be studied via individual tree analyses. Consequently, this thesis focuses on factors that might alter individual white spruce’ climate sensitivity and methods to assess such effects. In particular, the research articles included explore three topics:
1. First, clones were identified via microsatellites and high-frequency climate signals of clones were compared to that of non-clonal individuals. Clonal and non-clonal individuals showed similar high-frequency climate signals which allows to use clonal and non-clonal individuals to construct mean site chronologies. However, clones were more frequently found under the harsher environmental conditions at the treelines which could be of interest for the species survival strategy at alpine treelines and is further explored in the associated RESPONSE project A5 by David Würth.
2. In the second article, methods for the exploration and visualization of individual-tree differences in climate sensitivity are described. These methods represent a toolbox to explore causes for the variety of different climate sensitivities found in individual
trees at the same site. Though, overlaying gradients of multiple factors like temperature, tree density and/or tree height can make it difficult to attribute a single cause to the range of reaction norms (climate growth correlations).
3. Lastly, the third article attempts to disentangle the effect of age and size on climate-growth correlations. Multiple past studies found that trees of different Ages responded differently to climatic drivers. In contrast, other studies found that trees do not age like many other organisms. Age and size of a trees are roughly correlated, though there are large differences in the growth rate of trees, which can lead to smaller trees that are older than taller trees. Consequently, age is an imperfect Proxy for size and in contrast to age, size has been shown to affect wood anatomy and thus tree physiology. The article compares two tree-age methods and one tree-size method based on cumulative ring width. In line with previous research on aging and Wood anatomy, tree size appeared to be the best predictor to explain ontogenetic changes in white spruce’ climate sensitivity. In particular, tallest trees exhibited strongest correlations with water stress in previous year July. In conclusion, this thesis is about factors that can alter climate-growth relationships (reaction norms) of white spruce. The results emphasize that interactions between climate variables and other factors like tree size or competition status are important for estimates of future tree growth and potential treeline shifts. In line with previous studies on white spruce in Alaska, the results of this thesis underline the importance of water stress for white spruce.
Individuals that are taller and that have more competitors for water appear to be most susceptible to the potentially drier future climate in Alaska. While tree ring based growth trends estimates of white spruce are difficult to derive due to multiple overlaying low frequency (>10 years) signals, all investigated treeline sites showed highest growth at the treeline edge. This could indicate expanding range edges. However, a potential bottleneck for treeline advances and retreats could be seedling establishment, which should be explored in more detail in the future.
Class I and class II glutaredoxins (Grxs) are glutathione (GSH)-dependent proteins, that function as oxidoreductases (class I) or mediate cellular iron trafficking (class II). Some members of class I Grxs like human Grx2 are able to complex a [2Fe-2S] cluster and form a dimeric holo complex, which renders them catalytically inactive and is the basis for their function as redox sensors. Class II Grxs like human Grx5 also complex [2Fe-2S] clusters, however these proteins transfer the clusters to other proteins. Both functionally distinct classes share a similar thioredoxin fold and conserved interaction sites for the non-covalently binding of GSH, which is required to complex the [2Fe-2S] cluster. Furthermore, the proteins from both classes contain a highly nucleophilic active site cysteine that would allow both classes to catalyze GSH-dependent oxidoreduction reactions. Despite of these similar features, only class I Grxs are able to form a mixed disulfide with GSH and to reversibly transfer it to protein thiols (de-/glutathionylation). Interestingly, neither class I Grxs nor class II Grxs can effectively compensate the loss of an essential member of the other class. Even though some structural differences were described earlier, the basis for their different functions remained unknown. In particular, the lack of catalytic activity of class II Grxs as oxidoreductases could not be explained. Here, we demonstrate that the different conformations of a conserved lysyl side chain are the molecular determinant of the oxidoreductase or Fe-S transfer activity of class I and II Grxs, respectively. A specific loop structure that is conserved in all class II Grxs determines one lysyl conformation that prevents the formation of a mixed disulfide of the active site cysteinyl thiol with GSH. Using engineered mutants of hGrx2 and hGrx5, we demonstrated that the exchange of the distinct loop between the classes results in a loss of oxidoreductase function of class I hGrx2 and the gain of oxidoreductase activity of class II hGrx5. The altered GSH binding mode also profoundly changes the [2Fe-2S] cluster binding of the engineered mutants and thereby also influences stability of the holo complexes, a pre-determinant for [Fe-S] cluster transfer activity. With the minor shift of 2 Å in a conserved lysyl side chain orientation we were not only able to modify the catalytic activity of two small human mitochondrial proteins, but on a much larger scale also provided evidence for the previously unknown structural basis that determines the function of all class I and class II Grxs.
The oxidoreductase activity of hGrx2 was also analyzed in vivo in a model of doxorubicin cell toxicity. Applying a mass spectrometrical approach, we identified various mitochondrial proteins as targets for redox regulation. Furthermore, our results gave reason to reconsider some common assumptions regarding doxorubicin-induced apoptosis and the protective function of mitochondrial Grx2.
The worldwide distribution and prevalence of melioidosis, an infectious disease caused by the soil-dwelling Gram-negative bacterium Burkholderia pseudomallei, is unknown. In Vietnam, sporadic cases of melioidosis have been reported for decades, but clinical and epidemiological data for the indigenous population are still scarce. In this study, we reviewed clinical and demographic data of patients with culture-proven melioidosis diagnosed at a single large referral hospital in Hanoi between November 1997 and December 2005. The clinical manifestations of melioidosis with fatal septicaemia as the most common presentation, a high rate of underlying diseases and a peak of cases admitted during the wet season were similar to studies from other endemic areas. The geographical origin of melioidosis patients shows that melioidosis exists in at least 18 northern provinces. The characterization of clinical B. pseudomallei strains by multilocus sequence typing identified 17 different sequence types (STs), ten of which have (as yet) not been found outside Vietnam. Several of these STs presumably were generated through recent evolutionary events in this rapidly diversifying bacterial species, and thus restricted geographic distribution may be a consequence of limited time passed since emergence. In order to define the distribution of the bacterium in the environment, our study also aimed to develop a more sensitive culture method for the detection of B. pseudomallei from soil samples in endemic areas compared to the currently used culture method based on soil dispersion in water. Our newly developed protocol involving soil dispersion in a polyethylene glycol and sodium deoxycholate solution increased the yield of viable B. pseudomallei from soil samples. Comparative testing of soil samples from Northeast Thailand covering a wide range of B. pseudomallei concentrations demonstrated a significantly higher recovery (p < 0.0001) of B. pseudomallei colony forming units by the new method compared to the conventional method. Our data indicate that using the detergents polyethylene glycol and sodium deoxycholate not only results in a higher recovery of viable B. pseudomallei, but also results in a shift in the bacterial species recovered from soil samples. Molecular methods based on direct bacterial nucleic acid extraction from environmental samples and subsequent amplification have the potential to overcome many restrictions of traditional microbiological approaches. Moreover, culture-dependent methods require special expertise in recognizing B. pseudomallei colony morphologies. Thus, a highly sensitive culture-independent DNA-based method that allows direct quantification of B. pseudomallei from soil is needed, particularly in diagnostic laboratories outside endemic areas. We therefore aimed to establish a protocol for B. pseudomallei soil DNA isolation, purification and quantification by qPCR targeting a type three secretion system 1 single copy gene. This assay was validated using 40 soil samples from Northeast Thailand that underwent parallel bacteriological culture. All 26 samples that were B. pseudomallei-positive by direct culture were B. pseudomallei qPCR-positive, with a median of 1.84 x 104 genome equivalents (range 3.65 x 102 to 7.85 x 105) per gram of soil. This was 10.6 fold (geometric mean; range 1.1 to 151.3) higher than the bacterial count as defined by culture. Moreover, the qPCR detected B. pseudomallei in seven samples (median 36.9 genome equivalents per g soil; range 9.4 to 47.3), which were negative on direct culture. These seven positives were reproduced using a nested PCR targeting a second, independent B. pseudomallei-specific sequence. Two samples were direct culture and qPCR negative but nested PCR positive. Five samples were negative by both PCR methods and culture. In conclusion, this is the first report on a series of cases describing clinical and epidemiological features of melioidosis and corresponding Burkholderia pseudomallei strains from northern Vietnam. Moreover, our newly developed culture-based and PCR-based methods provide highly specific and sensitive tools for the quantitative environmental surveillance of B. pseudomallei.
The synthesis of pterin-dithiolene ligands was achieved by employing the radical nucleophilic substitution, i.e. the so-called “Minisci- Reaction”1. This protocol was used for the first time by Professor W. Pfleiderer on pterin substrates2 and proved a powerful method for the preparation of 6 acyl-pterins in course of this work. Subsequent construction of the dithiolene ring facilitates the synthesis of pterin-dithiolene ligands with completely unprotected pterin moieti.
The molybdenum cofactor is probably one of the most relevant discoveries in the recent history of pterin chemistry and biochemistry. Many efforts have been made for the preparation of compounds able to mimic the features of the Moco ligand system called "Molybdopterin". In fact, the study of MPT models enables a deeper understanding of the “mechanism of function” of this cofactor and most importantly, lays the foundation for a potential treatment for the Moco related diseases MoCOD and iSOD.
Destination Image, Tourist Satisfaction and Destination Loyalty: A Case Study of Hue, Vietnam
(2016)
Several studies have confirmed the interrelationship among destination image, tourist satisfaction and destination loyalty, in which destination image and tourist satisfaction are believed to have great influences on the destination loyalty of tourists. Located in the central region of Vietnam, Hue holds great potential for tourism development and this destination has also obtained numerous significant tourism achievements over recent years.Nevertheless, there are still a lot of issues needed to be addressed by the destination managers in order to make Hue gain a better position and higher level of destination loyalty in the tourism market, in which successfully communicating an attractive destination image to the tourists and improving their satisfaction are the most important tasks. In fact, there exist very few researches concerning destination image, tourist satisfaction or even destination loyalty which have been done in Hue. Moreover, most of these studies are in very small scale and they only examine either the destination image or the tourist satisfaction or the destination loyalty independently. This paper, therefore, aims to deliver the first and comprehensive theoretical and empirical analysis of destination image, tourist satisfaction and destination loyalty as well as the causal relationship among them in the context of Hue. In this study, a destination loyalty research model was proposed and hypotheses were derived. The empirical data base on two tourist surveys with a total number of 2042 questionnaires collected in Hue in 2013 and 2014. In addition, ten experts were interviewed in different periods during the study. The results find that the tourists’ perceptions on the destination image of Hue are quite positive and the positive level is higher for those who completely have no earlier experience in Hue. It is also discovered that the destination is offering tourists with a pretty satisfactory experience, not as high as their initial expectations, but acceptable with positive ratings received from the tourists. However, if the destination is able to better communicate a positive image to tourists and improves the quality of its offers and services, the tourists’ satisfaction will be increased and thus the destination loyalty will also be enhanced. This finding supports the proposed destination loyalty model: (1) destination image directly influences attribute-satisfaction; (2) destination image and attribute-satisfaction are both direct influences of overall-satisfaction; and (3) overall-satisfaction in turn has a direct and positive impact on destination loyalty. The findings also confirm that attribute-satisfaction and destination image are also the direct influences of destination loyalty. Furthermore, the results add to the proposed loyalty model a new relationship: Destination image is influenced strongly by tourist overall-satisfaction and attribute-satisfaction. The outcomes of this research are expected to be used as a valuable reference for the local policy-makers, governmental agencies, tourism companies and other relevant stakeholders. Also, important theoretical and managerial implications are drawn based on the study findings and the recommendations for future researchers are made from the limitations and scopes of the study.
I have investigated the role played by reactive oxygen species (ROS) generated by the phagocyte NADPH oxidase system in the innate immune response. I first looked at effector functions by asking whether ROS released from phagocytes might be effective in the killing of extracellular bacteria. Since bacteria can be killed in many other ways – for example by proteases or by cationic peptides – I made use of the recently demonstrated capacity of ROS to remove discontinuities from the surface of gold as the basis of an in vivo assay for extracellular ROS. Unlike bacterial killing, this readout system is not affected by enzymes, cationic peptides or other biological anti-bacterial agents. By this means I was able to use wild type mice and a congenic strain which lacks the gene coding for the gp91 subunit of the phagocyte NADPH oxidase to demonstrate that ROS generated by the NADPH oxidase system are indeed found outside the cells during an inflammation in vivo and that their principle source is neutrophil granulocytes rather than tissue macrophages. Since ROS released by these cells will be non-specific in its action it is to be expected that the releasing cell will itself suffer considerable damage. This fits well to the known short life of activated neutrophils and may explain the established fact that their death is dependent on the NADPH oxidase system. The long lived macrophages, in contrast, restrict their production of extracellular ROS. ROS are increasingly being found to be involved in both intra and intercellular signalling processes I looked for an involvement of NADPH oxidase derived ROS in the recruitment of neutrophils to sites of inflammation in vivo. Since the gene coding for the gp91 subunit of the NADPH oxidase is on the X chromosome I made use of a mosaic expression strategy based on X chromosomal inactivation. The results show that indeed ROS serves as a component of the neutrophil recruitment process in the critical early stages of an infection. Possible mechanisms are explored.
The present experimental work investigates plasma turbulence in the edge region of magnetized high-temperature plasmas. A main topic is the turbulent dynamics parallel to the magnetic field, where hitherto only a small data basis existed, especially for very long scale lengths in the order of ten of meters. A second point of special interest is the coupling of the dynamics parallel and perpendicular to the magnetic field. This anisotropic turbulent dynamics is investigated by two different approaches. Firstly, spatially and temporally high-resolution measurements of fluctuating plasma parameters are investigated by means of two-point correlation analysis. Secondly, the propagation of signals externally imposed into the turbulent plasma background is studied. For both approaches, Langmuir probe arrays were utilized for diagnostic purposes. The main findings can be summarized as follows: Greatly elongated fluctuation structures exist in plasma edge turbulence. The structures are aligned along the confining magnetic field (k|| = 0). The correlation degree of fluctuations for a short connection length of 0.75m is greater than 80%. For much longer connection lengths of 23m and 66m, the correlation degree is reduced to approximately 40%. A conceptual interpretation of these observations is the coexistence of two different fluctuation components. One component has a correlation length parallel to the magnetic field below 20m and the other component a correlation length greater than 70m. Sine signals in the frequency range 1-100 kHz were injected into the turbulent plasma background. The propagation parallel and perpendicular to the magnetic field of the signals was studied. In poloidal direction, an asymmetry is observed, that can be explained by a copropagation of the signal with the background E × B-rotation of the plasma. The signal propagation parallel to the magnetic field shows no such asymmetry. As an advanced approach, spatio-temporal wave patters were injected into the edge plasma. The waves launched that way can be seen as test waves' in a turbulent background. The coupling strength of the imposed wave patterns to the background turbulence relies on the match of the imposed waves to the dynamics of turbulent structures. If the propagation direction of the imposed waves is parallel to the propagation direction of the background plasma, improved coupling is observed. This finding underlines the importance of the background plasma rotation for future attempts of controlling the plasma edge turbulence. Further optimization of frequency and wave vector of the imposed waves is probably a promising approach for achieving a significant and systematic influence of turbulence. Taking into account the present experimental state-of-the-art, for a deeper insight into the mechanism of the plasma edge turbulence of magnetized high-temperature plasmas a joint effort of numerical modeling and experimental results is a valuable approach. Such a cooperation should cover the explanation of the correlation observations as well as the experiments on signal injection into background turbulence. A quantitative comparison between the results presented in this work and a dedicated numerical drift wave simulation would be a significant step forward to a better understanding of plasma edge turbulence.
Degradation of branched chain aliphatic and aromatic petroleum hydrocarbons by microorganisms
(2008)
The overall aim of the work was to investigate the ability of several Gram-positive bacteria including Mycocbacterium neoaurum SBUG 109, Nocardia cyriacigeorgica SBUG 1472 and Rhodococcus ruber SBUG 82 and the yeast Trichosporon mucoides SBUG-Y 801 to degrade and transform branched chain hydrocarbons which occur in petroleum and its fraction products such as gasoline or gas oil and which are known as important and recalcitrant environmental pollutants. Pristane, iso-pentylbenzene and sec-octylbenzene were used in this work as model compounds. These compounds represent significant groups of petroleum constituents (branched chain alkanes and aromatic hydrocarbons). Three bacteria and the yeast T. mucoides SBUG-Y 801 were selected in a screen of 16 hydrocarbon-utilizing strains in the SBUG collection and from 21 isolated hydrocarbon-utilizing strains from oil-contaminated habitats of Saudi Arabian Desert and of Vietnam. The bacteria were identified in cooperation with DSZM (Deutsche Sammlung von Mikroorganismen und Zellkulturen) as M. neoaurum SBUG 109, N. cyriacigeorgica SBUG 1472, R. ruber SBUG 82. These bacterial and yeast strains were shown to possess high potential for degrading and transforming pristane, iso-pentylbenzene and sec-octylbenzene. The intermediates produced by these bacteria during incubation with pristane were analyzed by GC and GC/MS. The products 4-methyl pentanoic acid; methyl butanedioic acid; 2-methyl pentadioic acid; methyl propanedioic acid; 4-methyl heptanedioic acid and 2,6,10,14–tetramethyl-pentadecan–3–one were detected in M. neoaurum cultures. In R. ruber, methyl butanedioic acid; 2-methyl pentadioic acid; 4,8-dimethylnonanoic acid, 4-methyl heptanedioic acid; 2,6,10–trimethylundecanoic acid; 3,7-dimethyl decanedioic acid and 2,6,10,14–tetramethyl–pentadecan–3-one were identified. In N. cyriacigeorgica, 2-methylpentanedioic acid; 4,8-dimethylnonanedioic acid; 2,6-dimethylheptanedioic acid and pristanic acid were found. The detection of 11 intermediates during pristane degradation by the three Gram-positive bacteria provided sufficient information to elucidate in detail three degradative pathways of pristane involving mono-, di- and sub-terminal oxidations. The sub-terminal oxidation by M. neoaurum and R. ruber was demonstrated for the first time. This occurence of a sub-terminal oxidation in these strains was strengthened by further results of aromatic compounds transformation (see below). During this pathway, ketone mono-oxygenation reactions seem to be involved. Because of this it will be of interest to look more closely at the catalytic processes involved and their possible extension to the bio-degradation of other branched chain hydrocarbons. Since in the present study 59 %, 51 % and 84 % of pristane were degraded in 3 weeks by M. neoaurum, R. ruber and N. cyriacigeorgica, this illustrated that the degradation rates of this isoprenoid alkane were high. The bacteria we studied were not only effective degraders of multiple branched chain alkane but also useful transformers of aromatic hydrocarbons. The intermediates produced were analyzed by comparing the retention times and UV/Vis spectra of the HPLC elution profile as well as the retention times and mass spectra of the GC/MS with those of available standards. Using iso-pentylbenzene as a substrate, 8 metabolites were generated by M. neoaurum transformation including product A (phenylacetic acid), B (acetophenone), D (iso-valerophenone), E (succinic acid), F (benzoic acid), G [(2-hydroxy-phenyl)-acetic acid] and H (2-methyl-4-phenyl-butyric acid). We additionally identified an alkyl hydroxylated iso-pentylbenzene derivative as 2-methyl-4-phenyl-butan-2-ol or 2-methyl-4-phenyl-butan-1-ol. Two metabolites (C and D) were detected by N. cyriacigeorgica transformation and three metabolites (A, D and F) were identified by R. ruber transformation which led to the complete biotransformation of this substance. iso-Pentylbenzene transformation by M. neoaurum was initiated by attack on the alkyl side chain followed by ring cleavage. The appearance of iso-valeorophenone confirmed the occurrence of a sub-terminal oxidation mechanism in M. neoaurum and R. ruber. In addition to products A, C, D and G, the identification X-(3–methyl–butyl)-phenol (X means that position of the hydroxy group on the aromatic ring system, such as 2, 3 or 4 remained unclear) in T. mucoides cultivation demonstrated for the first time the capacity of alkyl side chain attack by this organism which was hitherto known only for its ability of ring cleavage. The detection of 15 degradation products of sec-octylbenzene (including 2-phenylpropionic acid, 3-phenylbutyric acid, ß-methylcinnamic acid, 5-phenylhexanoic acid, acetophenone, 2-hydroxy-acetophenone, 2,3-dihydroxy-benzoic acid, succinic acid, 7-phenyloctan-2-one, benzoic acid, phenylacetic acid, 7-phenyl-octan-2-ol, hydroxy-phenylacetic acid and 2-hydroxybenzoic acid), in the studied bacteria pointed to an effective sec-octylbenzene degradation pathway in which dehydrogenation of 3-phenylbutyric acid to form ß-methylcinnamic acid is a newly described option. The identification of 2-phenylpropionic acid and 3-phenylbutyric acid in sec-octylbenzene transformation experiments by T. mucoides confirmed the possibility of alkyl side chain attack by this yeast. Summarizing the results, we describe for the first time in detail the biotransformation of sec-octylbenzene by M. neoaurum, N. cyriacigeorgica, R. ruber and T. mucoides. Our results suggest that these microorganisms may be useful as potential strains for hydrocarbon degradation and it may be of interest to investigate their suitability to solve specific environmental pollutant problems associated with branched chain aliphatic and alkyl-branched compounds which contribute to the persistence of hydrocarbon fractions in the environment.
Recent geochemical and mineralogical alteration processes in tropical coastal sediments of Vietnam
(2006)
The dissertation contains two main parts: (i) Syn-sedimentary hydrodynamic processes & relationship with elemental distribution, clay matter, (ii) Short-term mineral alteration during early diagenes. Samples were taken from the uppermost one metre (<50 year old in RRD, < 300 y old in south central VN). In part one, three principal hydrodynamic factors can be revealed based on End-Member Modelling Algorithm (EMMA), for the polymodal grain-size distribution patterns in coastline of VN (i) Accumulation factor: accumulation of terrigenous sediments linked with a grain size separation (distance dependence), (ii) Erosion factor: synsedimentary erosion by wave activities, (iii) Aeolian factor: deposition from neighbour sand bar by wind (typically only for low sedimentation rate, like in South Central Coast but not to detect in RRD). Distributions of clay matter and chemical elements in the coastal sediments in Vietnam are strongly influenced by hydrodynamic forces (distance from the coastline). In part two, particle-wise analysis by TEM allowed to determined four main mixed layer series: di-Vermiculite/Smectite-ml, Kaolinite/ Expandable-ml, Illite/Smectite-ml, Chlorite/Saponite-ml. Three principal mineral alteration processes can be detected in coastal sediments during early diagenesis: Dissolution, Smectitization, Kaolinitization, based on XRD (CSD, peak area) & TEM-EDX (particle morphology, chemical formula, polytype, particle frequency). Dissolution process of clay matter is typically in the coastal alkaline condition. It is a function of diagenetic time. Dissolution begins with a higher degree of dislocation and is followed by step-wise delamination & dissolution of the first stacks Smectitization (mirrored in diVS-ml series) alters mica-like structures (illite, dioctahedral vermiculite) to smectitic structures (Beidellite, Montmorillonite). Smectitization process occurs in group-wise layer by layer transforming mechanism (mica-like layer to smectitic layer). Each step is indicated by a gauss-like distribution of the octahedral layer charge with K as trigger. Kaolinitization of KE series alters smectitic structure (beidellite, smectitic KE-ml) to kaolinitic structure (kaolinitic KE-ml, kaolinite) "interlayer by interlayer" transformation of KE-ml series is comparable to kaolinitization mechanism discussed by Dudek et al. (2006).OH- groups in ambient could be the trigger. Mangroves biota influences the sediments in two main pathways: Nutrients supply & trapping function (clay matter, heavy metals)Interaction of active root-layer: intensification of dissolution, smectitization & kaolinitization: uptake of K, Na by mangrove root is possible trigger Human activities like shrimp cultivation have stopped the influences of the former active roots.Besides, erosion process related to water discharge gives rise to dispersion of clay species & heavy metals => more toxic for ecosystem.
The pollen record is a powerful proxy to reconstruct past terrestrial vegetation, but quantifying plant abundances is strongly limited because plants produce pollen in different amounts and pollen is dispersed differently. Further complications arise from the use of percentage data. Finally, a pollen grain deposited at a site may have arrived from proximate or distant sources, which implies that a single pollen sample may reflect very different vegetation scenarios. Present thesis suggests improving quantitative reconstructions of past vegetation by refined calibration of the pollen-vegetation relationship (paper I) and application of the downscaling approach (papers II-IV). Paper I primarily addresses the questions of pollen production and dispersal by calibrating the pollen-vegetation relationship. Data analysis employs the common extended R-value (ERV) approach and a new data-model comparison method, which appears more suitable than the ERV approach. For the first time PPEs have been calculated using three contrasting pollen dispersal options, including a Lagrangian stochastic (LS) model. The study proves that the underlying pollen dispersal model is a crucial parameter in PPE calculations and that the calculations with the LS model produce more reliable and realistic PPEs. Papers II to IV address quantitative reconstructions of past vegetation. Using the newly developed downscaling approach, the three studies explore fine scaled vegetation patterns in NE Germany during the Late Glacial and early Holocene. The main assumption of the downscaling approach is that the present day pattern of abiotic site conditions (e.g. the pattern of soil substrates) existed, at least to a large extend, also during the study periods. The basic principle of the approach is to test, whether pollen deposition in sites across a landscape is correlated to that site pattern. The first application of the approach (paper II) has shown a close correlation between PINUS pollen percentages and the distance weighted abundance of sandy soils and between BETULA pollen percentages and the distance weighted abundance of morainic till during the Allerød period, indicating that pine and birch formed rather separate stands on either substrate type. The cooling of the Younger Dryas induced significant changes in the vegetation of NE Germany. By combining pollen percentage and pollen accumulation rate data paper III identified a sharp vegetation boundary between the Mecklenburg and Brandenburg area at about 53 °N. The downscaling approach, here used with pollen accumulation rate data, suggests that in the North small tree stands could only exist in sheltered positions. The sharp vegetation boundary is possibly related to a climatic gradient and the southern permafrost limit, which itself may result from the formation of sea ice on the North Atlantic north of 53°N during winter. The warming of the Holocene again allowed the expansion of forests in the study area. Paper IV uses high resolution pollen (accumulation rate) data to study the successive forest formation, including the immigration of hazel, and explores vegetation patterns and composition during these successive stages using the extended downscaling approach. This approach addresses the problems related to differential pollen production, dispersal and the use of percentage data by applying simulations. It reveals that initially pine and birch established, as during the Allerød period, in largely separate stands with pine dominating on sandy soils and birch dominating on fine grained soils. Also open rich vegetation persisted, possibly due to seasonal drought, mainly on fine grained soils. Hazel later mainly spread on sites that received additional wetness from ground or surface water; it did not enter pine dominated forests on well drained sandy soils. Overall, the early Holocene vegetation of the study area was sharply differentiated by soil humidity and fertility. To conclude, present thesis has revealed vegetation patterns and species site preferences in NE Germany during three periods of the Lateglacial and early Holocene. The results improve our understanding of vegetation history in northern Central Europe, specifically for periods of rapid climate change. The approaches applied are flexible with respect to the type and quality of pollen data used and may be implemented using standard software packages.