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“Za Hranetsiu” – “Beyond the Border”: Constructions of Identities in Ukrainian-Canadian Literature
(2010)
Grounded in the literary and cultural studies, the dissertation “Za Hranetsiu” – “Beyond the Border”: Constructions of Identities in Ukrainian-Canadian Literature answers the question how identities of different Ukrainian immigrants and their offspring have been constructed, continuously developed and transformed in contemporary Canadian literature. The study simultaneously presents a discussion of postmodern identities, a concise historical survey of Ukrainian immigration to Canada in the nineteenth and twentieth centuries, and an overall picture of the exceptionally substantial body of Ukrainian-Canadian literature. Detailed literary analyses focus on seven Ukrainian-Canadian works: Sons of the Soil (1939-45/1959) by Illia Kiriak, Yellow Boots (1954) by Vera Lysenko, A Letter to My Son (1981) by George Ryga, The Green Library (1996) by Janice Kulyk Keefer, The Doomed Bridegroom: A Memoir (1998) by Myrna Kostash, Kalyna’s Song (2003) by Lisa Grekul, and The Ladies’ Lending Library (2007) by Janice Kulyk Keefer.
Many intrastate conflicts see more than one mediation effort. As the sequencing of mediation efforts in intrastate conflicts is neglected in existing research, this project addresses the question how and why previous mediation outcomes have an impact on subsequent mediation onset and subsequent mediation success. Drawing on bargaining theory, it is argued that governments and rebel groups engaged in intrastate conflicts account for previous mediation outcomes in their cost-benefit calculations on subsequent mediation onset, and, should subsequent talks set on, their behaviour during subsequent mediation efforts, which influences subsequent mediation success.
If mediation did not produce an agreement, the persistence of the private information problem is noted by the conflict parties. Yet, no new costs of mediation are uncovered, and hence the conflict parties will agree to subsequent mediation onset. Being aware of the necessity to overcome the private information and the commitment problem, the mediator will seek to account for the concerns of the conflict parties, and thereby work towards subsequent mediation success. If mediation produced a partial agreement, the benefits of mediation are underlined. The private information and the commitment problem seem solved with the assistance of the mediator. Subsequent mediation onset and eventually subsequent mediation success are observed. If a mediated agreement was reneged on by the rebel group, the government will refrain from further talks, pointing out the rebel group’s illegitimacy. If the government reneged on the agreement itself, it will also decide against subsequent mediation, as the previous mediation effort produced an agreement which did not mirror the power distribution in the dyad. Costs of mediation, which outweigh the benefits of it, were highlighted. Rebel groups will opt for mediation regardless which side reneged on an agreement. As both governments and rebel groups have to agree to subsequent mediation for talks to set on, subsequent mediation onset is unlikely if a mediated agreement was reneged on. Given the onset of subsequent mediation after a mediated agreement was reneged on, subsequent mediation success is unlikely to be observed, due to the previously underlined hazards of sharing private information and the persistence of the commitment problem.
The theoretical argument is tested with a mixed-methods approach. The quantitative analysis accounts for mediation efforts in African intrastate conflicts between 1993 and 2007. The qualitative analysis scrutinises the mediation efforts between the Government of Uganda and the Lord’s Resistance Army. The results of both parts of analysis largely go hand-in-hand, and show that partial mediation success and mediation which did not produce an agreement have a positive impact on subsequent mediation onset in particular, but also on subsequent mediation success. Reneged on mediated agreements have a severe negative impact on subsequent mediation onset and subsequent mediation success though.
By addressing the question which impact previous mediation outcomes have on subsequent mediation efforts, this research shows that mediation which does not produce an agreement is not the mediation outcome which needs to be feared by the international community. Instead, the deteriorating impact of short-lived agreements, a mediation outcome which is unaccounted for in existing research as an explanatory variable, becomes apparent. This research has important policy implications, especially for mediators, as it suggests that accepting mediation efforts to end without an agreement is more conducive for subsequent mediation efforts. Moreover, this research points towards the necessity of including reneged on agreements in mediation research as an explanatory variable more extensively, thereby shedding more light onto the dynamics at play in consecutive mediation efforts.
The thesis investigates the occurrence of the Early Modern European witch-hunt within the distinctively diverse society of the Grand Duchy of Lithuania. Positioned at the intersection of Latin and post-Byzantine cultures, along with Western and Eastern Christianity, this region lay on the frontlines of the Reformation and Counter-Reformation. The research aims to analyze the specific characteristics of the witch-hunt in this area, considering it a case study of social and cultural interaction within a borderland. It focuses particularly on identifying the distinctive aspects of the Lithuanian witch-hunt, examining the social and cultural roots of the witch trials, and exploring their relationship to the broader social and cultural developments of the period.
Central to this study is a detailed examination of the witch trials and an analysis of court materials. The thesis posits a socio-cultural interpretation of witch persecutions, arguing that they were culturally influenced manifestations of social tensions, enacted through legal mechanisms. The emergence of new Early Modern challenges, such as the social consequences of agrarian reform, the expansion of manorialism, and serfdom, led to novel tensions, conflicts, and responses, including accusations of witchcraft. The importation of authoritative foreign ideas about witchcraft reinvigorated, facilitated, and shaped pre-existing moderate indigenous beliefs, a process facilitated by religious struggles and Catholic post-Tridentine confessionalization. The Lithuanian legal system provided an environment conducive to an intensive witch-hunt, with witchcraft being a secular grave felony tried in highly decentralized and poorly supervised courts. However, this potential was largely unrealized. The study argues that the cultural diversity of the society played a major role in inhibiting the spread of Western witchcraft discourse, thereby limiting the extent of the witch-hunt in the Grand Duchy of Lithuania.
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.
In this thesis wave propagation in the whistler wave frequency range ωci≤ω≤ωce in the linear magnetized plasma experiment VINETA is investigated. The plasma is generated by a helicon antenna and has a diameter of about 10 cm. Whistler waves are launched by a loop antenna with a diameter of 4.5 cm and the fluctuating magnetic field is mapped by Ḃ-probes. Experiments are carried out for plasma parameters γ≤1/ √ 2 under which the only transversal polarized wave according to plane wave dispersion theory is the whistler wave. Due to the small collision frequencies ν≪1 cyclotron damping of whistler waves in this parameter regime is dominant and depends only on the electron plasma-β. The influence of the inhomogeneous plasma profile and excitation by a loop antenna is investigated by measurements of the fluctuating magnetic field perpendicular to the ambient magnetic field in azimuthal and radial axial planes. A mode characterized by the number of wave lengths m in the azimuthal direction is found. The mode structure is modified by the specific shape of the plasma density profile. Profiles with a homogeneous density inside the plasma radius are found to posses a comparably simple mode structure. An agreement in the mode structure of full-wave simulations in three dimensions, including a Gaussian density profile and excitation of the wave by a loop antenna, with the experimental results is found. Conclusions on the spatial structure of the excited mode are drawn using the simulations which predict excitation of an m=2 mode. The wave is found to be ducted within the plasma radius over a wide parameter range. A Helmholtz decomposition of the simulations electric field exhibits the fluctuating space charge as the dominant source for the electric field, while the contribution due to induction is negligible. The magnetic field is given partially by the electron and displacement current. Both contributions to the magnetic field are of the same order of magnitude. The frequency dependency of the excited modes spatial damping increment is investigated using measurements of the magnetic fluctuations along the symmetry axis of the plasma. In order to illustrate the parameter dependency, the electron plasma-β is varied over two orders in magnitude in the range β = 4·10-4 - 2.4·10-2. The experimental result for the spatial damping increment of the mode yields a strong damping for wave frequencies ω/ωce > 0.5 at maximum plasma-β, which shifts to higher frequencies with decreasing β. The parameter dependency of the damping for a fixed frequency is studied in an axial ambient magnetic field gradient. In both cases an excellent agreement between the experimental result and predictions for cyclotron damping from plane wave dispersion theory is found.
Overall, the present thesis provides tools for virus characterization. Importantly, the application of the developed tools contributed to the fundamental knowledge of selected, veterinary relevant viruses in terms of their underlying biology and virus-host interaction.
By using in vitro models and full-genome sequencing, important new findings were gained that contributed to the deeper understanding of the selected viruses. Results show that in vitro models can be successfully modified to enable study of specific host factors that are important for viral entry. By genetically modifying a bovine cell line using CRISPR/CAS9 technology , a stable cell culture model was established that is now available to the research community, to study the virus-host interaction of pestiviruses. The model was further used to elucidate the adaptability of bovine viral diarrhea the virus and impact on infectivity and growth. By using deep sequencing, genetic changes that occurred during the adaption process of bovine viral diarrhea virus were identified and linked to the phenotype, allowing the characterization of genetic regions important for virus binding to the host cell.
Whole-genome analysis using deep-sequencing was further used to characterize circulating rabbit haemorrhagic disease virus (RHDV) strains from Germany. The study provides more than 50 full genomes of RHDV strains sampled between 2013 and 2020. Since the virus family is drastically under sampled, in particular in central Europe, these sequences represent a very valuable addition to the field. The investigation led further to the discovery of a novel recombinant virus strain in hares, that is likely still circulating today. This finding is of special interest, since it is the first detection of a recombination event between the genogroups RHDV and European brown hare syndrome virus (EBHSV) of Lagoviruses. It highlights the importance of full genome virus surveillance and the potential risk of virus variants that might evade diagnostic detection.
Serological assay were used to study the persistency of antibodies developed during a natural infection with Schmallenberg virus. It could be shown that these antibodies are long lasting and therefore, re-emergence of this virus in Europe is likely favoured by introduction of naïve animals into a herd and not by decreasing antibody-titers over time.
Overall, the discoveries described in this thesis underline the importance of adequate tools for virus characterization and they give valuable answers to fundamental questions regarding the biology of the different viruses.
The layer-by-layer method is a robust way of surface functionalization using a wide range of materials, e.g. synthetic and natural polyelectrolytes (PEs), proteins and nanoparticles. Thus, this method yields films with applications in diverse areas including biology and medicine. Sequential adsorption of different oppositely charged macromolecules can be used to prepare tailored films with controlled molecular organization. In biomedical research, electrically conductive coatings are of interest. In manuscript 1, we investigated films sequentially assembled from the polycation poly (diallyldimethyl-ammonium) (PDADMA) and modified carbon nanotubes (CNTs), with CNTs serving as the electrically conductive material. We assume that charge transport occurs through CNT contacts. We showed that with more than four CNT/PDADMA bilayers, the electrical conductivity is constant and independent of the number of CNT/PDADMA bilayers. A conductivity up to 4∙10^3 S/m was found. It is possible to control the conductivity with the CNT concentration of the CNT deposition suspension. A higher CNT concentration resulted in thicker CNT/PDADMA bilayers, but in a lower conductivity per bilayer. We suspect that an increased CNT concentration leads to a rapid CNT adsorption without the possibility to rearrange themselves. If PDADMA then adsorbs on the disordered CNTs in the next deposition step, the average thickness of the polymer layer is thicker than on the more ordered CNT layer from the dilute solution. This leads to an increased PE monomer/CNT ratio and lower conductivity. More polycations between the CNT layers leads to less CNT contacts. Thus, the controlled composition of films can be used to fulfill specific requirements.
For many applications of polyelectrolyte multilayers (PEMs), cheap PEs with a broad distribution of molecular weights are used. It was unknown whether the distribution of molecular weights of the PE in the adsorption solution is maintained during the adsorption process and hence in the film. To investigate this, the PSS adsorption solution in article 2 consisted of a binary mixture of short and long poly (styrene sulfonate) (PSS). A good model system to study layered films in terms of composition are PDADMA/PSS multilayers. Neutron reflectivity and in-situ ellipsometry measurements were carried out to determine the PSS composition in the film and the growth regimes. At a mole fraction of long PSS of 5 % or more in solution, the exponential growth (which is characteristic of short PSS) is totally suppressed, and only long PSS is deposited in the resulting multilayer. Variation of adsorption time of PSS showed that short PSS first adsorbs to the surface but is displaced by long PSS. Between 0 and 5 % of long PSS in the adsorption solution exponential growth occurs. The fraction of short PSS in the film continuously decreases with the increase of long PSS in the adsorption solution. In the assembly of films prepared from binary PSS mixtures, the short PSS leaves the film through adsorption/desorption steps both during PSS adsorption and during PDADMA adsorption (as PDADMA/PSS complexes). Both techniques show that the composition of the film does not correspond to that of the deposition solution. The composition and thus the properties of the resulting multilayer are influenced by the choice of adsorption time. Moreover, we conclude that a multilayer grown from a polydisperse polyelectrolyte contains fewer mobile low molecular weight polymers than the deposition solution.
In manuscript 1 and article 2, the composition of multilayers was studied. In manuscript 1 adsorption kinetics were important for the arrangement of CNTs on the surface. In article 2, the adsorption kinetics, i.e. the diffusion of the polyelectrolytes to the surface, was also investigated. In article 3, we investigated the influence of the composition of the film as well as the preparation condition on the mobility of PEs in the film. The molecular weight of the polycation PDADMA and the NaCl concentration of the deposition solution were varied. The vertical PSS diffusion constant D_PSS within the PDADMA/PSS multilayers was measured using neutron reflectivity. The salt concentration of the preparation solution defines the polymer conformation during deposition. The molecular weight of the polycation determines the degree of intertwining. Together, both parameters determine the polyanion-polycation coupling and thus the PSS mobility within the network. Log−log display of D_PSS vs the molecular weight of PDADMA and fits to two power laws (D_PSS ∝ X_n(PDADMA)^(-m) ∝ M_w(PDADMA)^(-m)) reveals for films built from 10 or 200 mM NaCl a kink. Below and above the kink, the dependence of D_PSS on M_w(PDADMA) can be described by different power laws. For Χ_n(PDADMA) < X_n,kink(PDADMA) ≈ 288, the exponents are consistent with the predictions of the sticky reptation model. X_n(PDADMA) ≈ 288 is the entanglement limit. For Χ_n(PDADMA) > X_n,kink(PDADMA) ≈ 288, the decrease of D_PSS with M_w(PDADMA) is larger than below the entanglement limit, which is indicative of sticky reptation and entanglement. The PSS diffusion constant of films built from 100 mM NaCl drops three orders of magnitude when increasing the molecular weight of PDADMA from 45 kDa to 72 kDa. To figure out if an immobile PSS fraction exists in the film built from 72 kDa PDADMA (beyond the entanglement limit), the film was annealed at different conditions in article 4: both temperature and salt concentration were varied. For data analysis, the simplest model with two PSS fractions with different diffusion constants was used. These diffusion constants increase as the temperature of the surrounding solution is increased. As assumed in article 3, an immobile PSS fraction exists when annealing at room temperature. At higher annealing temperatures, at least two diffusion processes must be distinguished: the diffusion of the highly mobile PSS fraction through the entire film and a slow PSS fraction, mowing in a limited way. The choice of preparation conditions determines whether a polyelectrolyte multilayer can intermix completely. It is not clear if complete intermixing will ever occur for films built with PDADMA beyond the entanglement limit. It is possible that the diffusion is more complex. Long-term measurements will clarify this question. Calculating scattering length density profiles with subdiffusive behavior would be interesting and is a challenge for the future. Furthermore, immobile fractions are only visible with long annealing times. We hypothesize that an immobile or nearly immobile fraction is present whenever the dependence of D_PSS on the molecular weight of PDADMA cannot be described by the sticky reptation. To verify this hypothesis, further studies are necessary.
All results presented and discussed in the manuscript and articles show that by varying the preparation conditions, tailored films can be built. The composition of the film is also determined by the adsorption kinetics. In addition, the mobility of the PEs within the multilayers can be controlled by varying the conformation, mingling and entanglement of the chains within the film. The influence of the salt concentration in the preparation solution on the growth regimes during film formation is part of our future research. It is planned to investigate films built of different PDADMA molecular weights under varied annealing conditions to better understand the mobile and immobile fractions.
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).
Vegetation dynamics on abandoned terraces of Sicily: the course and driving factors of succession
(2007)
Secondary succession processes have been widely studied in Europe for some agroecosystems, but not for terraced ones. The first part of the present study focuses on a description of the plant communities involved in secondary succession processes on Sicily (Italy) a) from a floristic and structural point of view and b) from a species diversity point of view. In order to obtain these results, 129 vegetation relevés (sensu Braun-Blanquet) were made on abandoned terraces in five of the main terraced areas of Siciliy: 1) the Aeolian Islands, 2) Pantelleria Island, 3) Mt. Etna, 4) the Palermo Mts. and 5) the Hyblaean Plateau. Only abandoned vineyards or grain crop fields were selected as sample plots, always 50 m2-sized. The results of biodiversity evaluation by t-tests and ANOVA showed that vascular plant diversity is linked to disturbance regime and to abiotic factors (especially geological substrate). Especially grazing increases species richness. Moreover, it was found that on limestone species richness is higher than on volcanic substrates. Vegetation relevés were also analysed with DCA and TWINSPAN. The resulting 14 sample plot groups (= clusters) were then used to check the dynamic relations. From a floristic point of view, plant communities involved in secondary succession processes on Sicilian terraces are quite different between and within the five study areas. This is mainly due to different substrate and bioclimatic conditions. Moreover, vegetation is strongly influenced by abandonment age and disturbance status. If no disturbance biases succession, then plant communities evolve rather rapidly (30-50 years) to maquis communities. If frequent fires or intense grazing occur, secondary succession is blocked in a "steady state". The second part of the present study focuses on the colonization mechanisms of old fields by woody species. In a first section, the existence of 1) the neighbourhood effect and 2) the safe-site effect are checked by analyzing 51 transect relevés, made up of 357 subplot relevés (1x1m). The transects were made in target fields 1) with older neighbour (i.e. old succession stage characterized by maquis communities) and 2) with older neighbour absent within a 100 m-distance. All woody species individuals were counted, recording if they grew within the influence of a potential safe site (former crop plants of vine and the terrace wall base). Data evaluation by Kruskal-Wallis ANOVA and Mann-Whitney Rank Sum confirmed the existence of the two effects. Moreover, it was shown that animals as dispersal vectors strongly influence these effects. For the neighbourhood effect, seed dispersal distance is the crucial point, while for the safe site effect 1) passive facilitation (i.e. animals tend to create heterogeneous seed rain patterns because they frequent certain microhabitats more often than others) and 2) active facilitation (i.e. the positive influence of an existing woody or herbaceous plant individual on the establishment or the growth of another one) are crucial. The second section describes the performance of establishment of Quercus ilex L. in different microsites of terraced old fields. In November 2004, acorns were buried on a North-facing slope and on a South-facing slope in five different microsites: 1) under vine plants, 2) at wall bases, 3) under the canopies of isolated shrubs, 4) between small rock accumulations and 5) in open spaces (i.e. outside of any of the previously named microsites). In monthly checks, seedling emergence, survival, height and leaf number were recorded. Moreover, in April and July were measured air temperature and air humidity in the different microsites. Overall emergence rate was 52.4% (n = 1,020). More seedlings emerged on the South-facing slope (S; 59.8%) than on the North-facing slope (N; 45.0%). Emergence was higher when acorns were buried under vine plants and at the wall base than in other microsites of the old fields. At the end of the experiment (September 2006), 45.3% of all emerged seedlings were still alive (29.2% on N, 58.9% on S). Survival was higher in general on the South-facing slope, and higher under vine plants and at the wall base than in the open spaces of the old fields. From literature, it is known that seed vitality, seed germination and seedling survival of Quercus ilex are favoured by shady, wet and fresh conditions. The temperature and air humidity measurements showed that at the wall base, under vine plants and under isolated shrubs environmental conditions are milder than in open spaces. However, even if temperature and relative air humidity seem to play an important role for Quercus ilex seedling emergence and survival, they did not unambiguously explain the differences between the safe site types. A factor of major importance is probably soil moisture. As a last part, the present study discusses what does the obtained results mean for terrace landscape conservation and biodiversity management.
Background: High resolution three-dimensional (3-D) magnetic resonance imaging (MRI) is widely used to predict the neurovascular anatomy within the cerebellopontine angle. Objective: To assess value of 3-D three-dimensional Steady-state free precession imaging (SSFP) and Time-of-flight magnetic resonance angiography (TOF MRA) and in detecting the offending vessels in hemifacial spasm by comparison to intraoperative endoscopic visualization. Methods: 42 patients underwent endoscope-assisted microvascular decompression (MVD). All available preoperative 3-D SSFP and TOF MRA images were checked. Intraoperative videos were captured by a high definition endoscopic camera attached to endoscopes while exploring the area of facial nerve root exit zone (REZ). Evaluation of the 3-D images was performed by two independent groups of observers and compared with the operative findings. Results: 3-D MRI had an average positive predictive value (PPV) of 89.1% in differentiating between simple and complex compression. Mean accuracy of the before mentioned images in detection of the offending vessels was 83.3% and 77% according to the first and second group of observers respectively. Averaged inter-observer agreement between the two groups of observers was substantial with an averaged Kappa coefficient (K) of 0.56. In simple compression group, mean accuracy was 97% and 89.4% according to the first and second group of observers respectively. Averaged K for agreement was substantial (K=0.65). Conclusion: According to endoscopic visualisation, 3-D SSFP and TOF MRA images are accurate in detecting the offending vessels in simple compression of the facial nerve, and in predicting presence of a complex compression with variable sensitivity in identifying all offending vessels.
Urban Green Areas – their functions under a changing lifestyle of local people, the example of Hanoi
(2013)
Hanoi is a rapidly developing city - in terms of area, population and economy. It also has to face social and environmental problems that often accompany the fast development of a city. Increasing environmental pollution leads to a decrease in living conditions, such as clean water, housing, social services, etc., for most of the city’s inhabitants. Other well-known social problems in cities worldwide also occur in Hanoi nowadays, for example inequality, food supply, and unemployment. In addition, the society is altering; lifestyle- change is a permanent process. Today, it seems that the changing process in Asian countries is rather leap-frogging than continuously. Although many research projects concerning to urban green areas in Hanoi have been completed recently, less is known about utilization of parks&gardens in a practical and systematic way. This study aims at contributing to fulfills the gaps with up-to-date facts and figures of parks’ utilization in the inner city of Hanoi. Based on “grounded theory”, triangular methodology was applied to collect empirical data in four main parks in the inner city of Hanoi namely: Thong Nhat, Bach Thao, Hoan Kiem, and Lenin. Scientific observations, visitor countings were done in 2010-2011; including 2143 face-to-face interviews to park users covering the course of the year and a small online-poll of 113 responses. Thirteen interviews with experts have been done in several phases and taken into account for discussing and testing hypotheses. Empirical results have shown that utilization of the parks is in abundance in terms of the use - numbers as well as activities. A comparison between the courses of the day for parks in Berlin and Hanoi shown that the time of using parks in Hanoi is earlier in the day. In details, there is 25% and 1.4% of total daily visitors went to parks in Hanoi and Berlin,, respectively. However, the biggest peak in park-visiting time for both cities is in the afternoon. The findings also clarified that students and retirees are the major users even though there is some different in structures of park user among the four parks. The length of stay depends on how large and interesting a park is. In this aspect, Hanoi parks are very poor in facilities showing by a long list of missing facilities in the parks. However, as there is no alternative, parks in Hanoi still attract a high number of visitors. In general, results from this study have shown a close relationship among socio-economic and political situations in Vietnam with UGAs and its utilization. Influencing factors on parks’ utilization were also indentified, which are social changes, lifestyle changes, economic situation, conflicts in land usage, and maintaining cost for UGAs. Three given hypotheses were confirmed: i) the demand of public UGAs in inner Hanoi will grow mid-term and increase strongly long-term; ii) Hanoi’s residents will claim strongly for more parks in the future; ii) The number of conflicts inside the area of UGAs, among the visitors will occur very soon and require a specific master plan for the development and the management of UGAs. Finally, based on the weaknesses of UGAs in Hanoi recently, two groups of recommendations were also suggested to improve UGAs. Firstly, in terms of quality – quantity: • Retain each square meter of green space as UGA – do not unblock any green space for construction; • The existing UGA have to be well maintained. Secondly, in terms of management – planning: • Elaborate a UGA-masterplan for (inner) Hanoi; • Keep UGA management in the responsibility of public bodies; • Implement participation of affected population defector in the process of planning and management (as it has already been written in planning guidelines); • Be aware of potential conflicts among park user groups; • Establish an UGA monitoring system – involving regular (or even permanent) countings based on up-to-date technology; Realize horizontal partnering structures.
Streptococcus pneumoniae (the pneumococcus) is a harmless resident of the human nasopharyngeal cavity, and, in general, every individual is likely to be colonized asymptomatically at least once during life. However, under certain conditions, the bacterium can spread to other tissues and organs causing local, non-invasive infections but also lifethreatening, invasive diseases. Pneumococcal carriage and infection is a highly regulated interplay between pathogen- and host-specific factors and the intimate contact of S. pneumoniae with the surface of the nasopharynx is the crucial step in pneumococcal pathogenesis. Pneumococcal adherence to the respiratory epithelium is mediated by surface-exposed adhesins. These adhesins engage host cell receptors either directly or indirectly by recognizing glycoproteins of the extracellular matrix (ECM) including structural components, such as collagens, laminins, and fibronectins, as well as plasma-derived ECM modulators, like vitronectin and Factor H. Pneumococcal surface protein C (PspC) is a surface-exposed protein and important virulence factor of S. pneumoniae. The multifunctional PspC protein promotes pneumococcal adherence to host cells by interacting with the secretory component of the human polymeric Immunoglobulin receptor of respiratory cells. In addition, PspC facilitates pneumococcal immune evasion by recruiting the complement inhibitor proteins C4b-binding protein (C4BP) and Factor H. Moreover, Factor H bound to the pneumococcal surface promotes bacterial adhesion to human epithelial and endothelial cells. S. pneumoniae also interacts with the human glycoprotein vitronectin. In plasma, monomeric vitronectin regulates thrombosis, fibrinolysis and the terminal complement cascade, while it additionally mediates cell-matrix interactions, cell adhesion and migration in the ECM. It was shown that multimeric, ECM-associated vitronectin facilitates pneumococcal adherence to respiratory epithelial cells. In addition, the interaction of pneumococci with vitronectin promotes their uptake by mucosal epithelial cells via the engagement of the integrin αvβ3 receptor and activation of intracellular signaling pathways culminating in cytoskeletal rearrangements. This study aims to identify and characterize the surface-exposed protein(s) that mediate binding of pneumococci to vitronectin and to elucidate the impact of vitronectin on pneumococcal pathogenesis beyond its function as molecular bridge between pneumococcus and host. Flow cytometric, immunosorbent and surface plasmon resonance experiments revealed that PspC is a vitronectin-binding protein of S. pneumoniae. The specificity of the interaction with vitronectin was confirmed using recombinant PspC proteins and Lactococcus lactis heterologously expressing PspC on their surface. Factor H did not hinder vitronectinbinding to PspC indicating that vitronectin recognizes the central part of PspC. Secretory IgA inhibited but not completely prevented vitronectin-binding to PspC, strongly suggesting that vitronectin binds near, but not directly to, the SC-binding region within the R domain(s) of PspC. In addition, PspC proteins comprising two R domains bound with higher affinity to vitronectin than PspC containing only one R domain, indicating that two interconnected R domains are required for efficient vitronectin-binding. Despite the sequential and structural differences to classical PspC, the PspC-like protein Hic specifically interacted with vitronectin with similar affinity than PspC containing two linked R domains. Binding studies confirmed that Factor H interacts with the very N-terminal region of Hic showing high sequence homology to classical PspC proteins, while vitronectin recognizes an adjacent region in the N-terminal region of Hic. The studied PspC proteins bound to both soluble and immobilized vitronectin, and the C-terminal heparin-binding domain (HBD3) was identified as PspC-binding motif in soluble vitronectin. However, in its immobilized form, vitronectin likely exposes additional binding sites for PspC since a region N-terminally to the identified HBD3 conferred binding of PspC. Vitronectin inhibits the terminal complement pathway, thereby preventing proinflammatory immune reactions and tissue damage. In general, pneumococci are protected from opsonization and MAC-dependent lysis by their capsule. However, pneumococci in close contact to human cells can become susceptible to complement attack due to reduced amounts of capsule. In addition, they can be severely affected by TCC-induced inflammatory responses. Vitronectin bound to PspC significantly inhibited the formation of terminal complement complexes. Thus, the interaction of PspC with vitronectin might aid in immune evasion of S. pneumoniae by inhibiting complement-mediated lysis and/or suppressing proinflammatory events. In conclusion, the results revealed the multifunctional PspC and Hic as vitronectin-binding proteins and proposed a novel role for the specific interaction of S. pneumoniae with vitronectin in regulating the complement cascade, beside its function as molecular bridge to the respiratory epithelium.
Autoclaved aerated concrete (AAC) is a building material that combines heat insulation
properties with sufficient mechanical strength for masonry construction. Compared to
ordinary concrete, the matrix is highly porous (>50%) and hardened by a hydrothermal curing
process at 150°C - 200°C. During this process, quartz sand and portlandite react to form first
calcium silicate hydrates (C-(A)-S-H) with Ca/Si ratios <1.3 and then tobermorite. Especially
tobermorite, which has a much larger crystallite size than C-(A)-S-H, provides improved
mechanical strength. This reaction sequence is influenced by many parameters and
additives of which calcium sulfate is probably the most important. Despite several attempts to
investigate these hydrothermal reactions, the actual reaction mechanism involved when
adding sulfate ions is not fully understood. It has been suggested that the addition of ca.
1.5 wt% significantly improves the mechanical properties due to the enhanced formation and
arrangement of tobermorite in the porous matrix. Since the sulfate content in AAC waste is
exceeding regulatory threshold for low-quality reuse in some countries, the aim of this study
was to investigate in detail the reaction mechanisms involving sulfate addition. Such
knowledge may open up the possibility to improve AAC production and to avoid the need for
sulfate addition. To achieve this goal, this research work focused on investigating the
hydrothermal curing process to determine the sequence of hydrothermal reactions and the
spatial distribution of the phases formed. For this purpose, a new setup for in situ X-ray
diffraction was specifically designed to study hydrothermal reactions and to conduct time
intensive experiments on a normal laboratory diffractometer. In order to quantitatively
evaluate the in situ measurements by Rietveld analysis using TOPAS, it was also necessary
to develop atomistic structure models for C-(A)-S-H phases. This was made possible by
adopting a supercell approach that was previously used to describe turbostratically stacked
clay minerals. The structure models, derived from tobermorite, are placed in an otherwise
empty supercell to simulate the C-(A)-S-H nanostructure. Adopting these methodological
advances, it was possible to obtain absolute phase quantities from in situ data and to track
the reaction kinetics of the hydrothermal curing process. These results were then combined
with ex situ X-ray diffraction and scanning electron microscopy. Confirming previous studies,
the major effect of sulfate ions was the formation and decomposition of hydroxylellestadite. It
was further revealed that C-(A)-S-H formation was delayed during hydroxylellestadite
formation, which is supposed to support the silicate ion diffusion and hence the tobermorite
formation at a stage critical for improved hardening of AAC. This can be linked to the
formation of lower amounts of capillary pores in the range of 1-5 µm, as observed by
scanning electron microscopy, and therefore a lower concentration of inherent defects that
resulted in the improved mechanical properties. This research work highlights how important the spatial distribution of crystallites is for the properties of a building material and how this
distribution can be influenced by small alterations in reaction chemistry.
In this work, the investigation of dusty plasma by means of tunable diode laser spectroscopy was carried out. Special interest was focused on the interactions of dust particles and metastable atoms. At first, Al density and temperature in dc and pulsed magnetron discharges were measured. Measurements with argon as working gas show an expected behavior of the measured atom density and temperature. Decrease of absorption signal was observed in argon/oxygen and argon/methane mixtures. A small admixture of oxygen leads to a complete disappearance of the absorption signal indicating vanishing Al atom density. The effect is believed to be caused by the oxidation of the magnetron target. This decrease reveals typical hysteresis behavior caused by poisoning of the target. Significant difference between critical oxygen flow value in dc and pulsed modes was registered. Then dust formation and plasma behaviors in hydrocarbon containing plasmas were analysed. The dust growing plasmas (Ar/C2H2, Ar/CH4 and Ar/C3H6 rf plasmas) were characterized by laser transmission and scattering methods, ion energy distribution function and mass spectrum evolution by plasma processing monitor, and the spatial distribution in pristine plasma and the temporal behavior of the metastable atom density in processing plasma using TDLAS. Pristine plasma were then characterized in term of metastable density and temperature. The radial distribution of neon metastable atom density in capacitive coupled rf discharge can be approximated to a Gaussian profile with the width smaller than plasma chamber radius. The diffusion flow of metastable atoms deduced from their spatial density distribution gives the loss of metastable atom in the plasma sheath. Argon metastable density was measured in rf plasma and compared with a simple model for metastable density. The model explains well the trend of metastable density with respect to the change of plasma input power. Metastable density of dusty plasma with injected dust particles was measured and compared to that of pristine plasma. The particle heating by metastable atoms was strongly evidenced. The power absorbed by dust particles due to bombardment of metastable atoms onto a dust particle surface in our experiments is about 0.04 Wm-2 for the low dust density case and lower for higher dust density which is in the same order as the contributions of kinetic energy of ions and electrons and the energy released by their recombination on the grain surface. The influence of dust particle density and size on metastable density was studied. Through measuring metastable density, TDLAS can be used as a tool to study the dust growth process in processing plasma.
Pancreatic ductal adenocarcinoma (PDAC) is one of the most aggressive malignancy and projected to be the third leading cause of cancer related death by 2030. Despite extensive knowledge and insights into biological properties and genetic aberrations of pancreatic ductal adenocarcinoma cells, therapeutic options remain temporary and ineffective. One plausible explanation for the futile response to therapy is an insufficient and nonspecific delivery of anticancer drugs to the tumor site. Superparamagnetic iron oxide nanoparticles (SPION) coupled with siRNA targeted against the cell cycle specific serine-threonine-kinase, Polo-like kinase-1 (siPLK1-StAv-SPIONs) could serve a dual purpose for delivery of siPLK1 to tumor and noninvasive assessment of delivery in vivo. siPLK1-StAv-SPIONs were designed as theranostics to function via a membrane translocation peptide (MPAP-) as well as a tumor selective peptide (EPPT-1) to increase intracellular delivery and tumor specificity, respectively. In vitro and in vivo experiments using a syngenic orthotopic PDAC model as well as the endogenous LSL-KrasG12D,LSL-Trp53R172H,Pdx-1-Cre model revealed significant accumulation of siPLK1-StAv-SPIONs in PDAC resulting in efficient PLK1 silencing. Tumor specific silencing of PLK1 halts tumor growth, marked by decrease in tumor cell proliferation and increase in apoptosis. siPLK1-StAv-SPIONs are well tolerated with no observed systemic side effects. Our data suggests, siPLK1-StAv-SPIONs with dual specificity residues for tumor targeting and membrane translocation, represent an exciting opportunity for targeted therapy in PDAC.
The confinement of energy has always been a challenge in magnetic confinement fusion devices. Due to their toroidal shape there exist regions of high and low magnetic field, so that the particles are divided into two classes - trapped ones that are periodically reflected in regions of high magnetic field with a characteristic frequency, and passing particles, whose parallel velocity is high enough that they largely follow a magnetic field line around the torus without being reflected. The radial drift that a particle experiences due to the field inhomogeneity depends strongly on its position, and the net drift therefore depends on the path taken by the particle. While the radial drift is close to zero for passing particles, trapped particles experience a finite radial net drift and are therefore lost in classical stellarators. These losses are described by the so-called neoclassical transport theory. Recent optimised stellarator geometries, however, in which the trapped particles precess around the torus poloidally and do not experience any net drift, promise to reduce the neoclassical transport down to the level of tokamaks. In these optimised stellarators, the neoclassical transport becomes small enough so that turbulent transport may limit the confinement instead. The turbulence is driven by small-scale-instabilities, which tap the free energy of density or temperature gradients in the plasma. Some of these instabilities are driven by the trapped particles and therefore depend strongly on the magnetic geometry, so the question arises how the optimisation affects the stability. In this thesis, collisionless electrostatic microinstabilities are studied both analytically and numerically. Magnetic configurations where the action integral of trapped-particle bounce motion, J, only depends on the radial position in the plasma and where its maximum is in the plasma centre, so-called maximum-J configurations, are of special interest. This condition can be achieved approximately in quasi-isodynamic stellarators, for example Wendelstein 7-X. In such configurations the precessional drift of the trapped particles is in the opposite direction from the direction of propagation of drift waves. Instabilities that are driven by the trapped particles usually rely on a resonance between these two frequencies. Here it is shown analytically by analysing the electrostatic energy transfer between the particles and the instability that, thanks to the absence of the resonance, a particle species draws energy from the mode if the frequency of the mode is well below the charateristic bounce frequency. Due to the low electron mass and the fast bounce motion, electrons are almost always found to be stabilising. Most of the trapped-particle instabilities are therefore predicted to be absent in maximum- J configurations in large parts of parameter space. Analytical theory thus predicts enhanced linear stability of trapped-particle modes in quasi-isodynamic stellarators compared with tokamaks. Moreover, since the electrons are expected to be stabilising, or at least less destabilising, for all instabilities whose frequency lies below the trapped-electron bounce frequency, other modes might benefit from the enhanced stability as well. In reality, however, stellarators are never perfectly quasi-isodynamic, and the question thus arises whether they still benefit from enhanced stability. Here the stability properties of Wendelstein 7-X and a more quasi-isodynamic configuration, QIPC, are investigated numerically and compared with another, non-quasiisodynamic stellarator, the National Compact Stellarator Experiment (NCSX) and a typical tokamak. In gyrokinetic simulations, performed with the gyrokinetic code GENE in the electrostatic and collisionless approximation, several microinstabilities, driven by the density as well as both ion and electron temperature gradients, are studied. Wendelstein 7-X and QIPC exhibit significantly reduced growth rates for all simulations that include kinetic electrons, and the latter are indeed found to be stabilising when the electrostatic energy transfer is analysed. In contrast, if only the ions are treated kinetically but the electrons are taken to be in thermodynamic equilibrium, no such stabilising effect is observed. These results suggest that imperfectly optimised stellarators can retain most of the stabilising properties predicted for perfect maximum-J configurations. Quasi-isodynamic stellarators, in addition to having reduced neoclassical transport, might therefore also show reduced turbulent transport, at least in certain regions of parameter space.
1. The study confirms an association between transverse arch dimensions and severity of ankyloglossia, which reflects relationship between molar difference and free tongue. 2. Molar difference in group A (complete and severe ankyloglossia cases) has high negative values (average -4.38) which was much smaller than the data from the literature concerning many different types of occlusion. 99 3. The exact relation between transverse arch dimension and severity of ankyloglossia needs further research.
Being the victim of traumatizing events has consequences that can lead to wellknown mental disorders, such as depression. However, newest studies show that these events do not only affect the victims’ behavior, but also the expression levels of specific genes in their blood and in their brain. Latest research discovered little pieces of RNA in the cells that were long thought to be genetic junk. Nevertheless, these so-called miRNAs can regulate the expression of multiple genes, thus modulating metabolism and cell functioning. The aim of this study was to see if childhood traumatization led to a set of differentially expressed miRNA profiles in the peripheral blood. For this, we used subjects from the SHIP trend cohort, who had previously answered various questionnaires, among them the Childhood Trauma Questionnaire and the Patients Health Questionnaire-9 and analyzed the miRNAs in their blood to find out whether there was an association between the score and the dysregulation of certain miRNAs. Furthermore, we selected 5 different independent variables: PHQ-trend, CTQ score, as well as its subscales Abuse and Neglect, and Major Depressive Disorder lifetime prevalence. The analyses showed a set of up- or downregulated miRNAs in the blood. In a second step, we tried to replicate our results comparing them to results in the literature. Some of the significantly dysregulated miRNAs had previously been described as key players in the pathogenesis of MDD, a few even displaying similar results to ours. The next step was to see if the significant miRNAs had common target genes and if these had been described in the literature as having an influence on MDD, showing positive results. One last step was to see if there were also common biological pathways that were modulated by the differentially expressed miRNA. This analysis did not show promising results since there were almost no brain pathways among the results. For future studies, it will be necessary to validate our results using a clinical sample, such as GANI_MED, where the prevalence of childhood traumatization, as well as MDD, is much higher. By doing this, new possibilities of trauma treatment through modulation of epigenetic pathways could arise. If childhood traumatization leads to a set of dysregulated miRNAs that can end in a positive diagnosis of MDD in adulthood, what effects could have a targeted miRNA therapy on the pathogenesis of these psychiatric disorders?
Tidal flats represent the transition zone between the terrestrial and marine realm. They are subject to pronounced dynamics due to distinct tidal and seasonal variations of physical, chemical, and biological parameters significantly influencing redox-sensitive element cycles. Thus, redox-sensitive trace metals may be suitable indicators for variations in bioproductivity and microbial activity. Therefore, seasonal and tidal dynamics of manganese, iron, molybdenum, uranium, and vanadium were studied in the water column and sediments of tidal systems of the German Wadden Sea (southern North Sea) in the years 2007 to 2009 involving also previously analysed data from year 2002. To demonstrate the response of the trace metal cycles on phytoplankton blooms and enhanced biological activity time series data of nutrients and phytoplankton dynamics were also involved in this study. Pronounced cycling is seen for pelagic manganese revealing distinctly higher values during low tide. Complex seasonal cycling showing maxima of dissolved manganese in spring and late summer and a depletion period in early summer is caused by benthic-pelagic coupling and reflection of exhaustion and replenishing periods in the surface sediments. Vanadium dynamics are coupled to the manganese cycling due to vanadium scavenging and release during manganese oxide formation and reduction, respectively. Molybdenum and uranium behave almost conservatively following changes in salinity and thus, being slightly enhanced during high tide. Deviations from conservative behaviour are found to occur during breakdowns of summer phytoplankton blooms. In the following, significant enrichments of manganese, molybdenum, iron, and uranium are observed in the shallow pore waters. These coherences are assumed to be caused by a tight coupling of geochemical, biological, and sedimentological processes. Intense release of organic matter during the breakdowns of algae blooms leads together with enhanced bacterial activity in summer to the formation of organic- and trace metal-rich aggregates which are deposited and incorporated into the tidal surface sediments. Microbial decomposition of the aggregates and corresponding shifts in redox-conditions effect a release of dissolved trace metals into the pore water. Subsequently, the trace metals are fixed in the sediment as sulphides, adsorbed to organic compounds or released to the overlying bottom water. Furthermore, two tidal systems, one from the East Frisian and one from the North Frisian Wadden Sea are compared. Although, both areas show different hydrodynamical, sedimentological, and ecological conditions similar manganese dynamics are observed implying that this is a common behaviour in the entire Wadden Sea. However, distinct quantitative differences appear showing a 6-fold higher level of dissolved manganese in the water column of the East Frisian area. This is explained by a higher manganese release from tidal flat sediments and a larger sediment area/water volume ratio compared to the North Frisian area. Detailed time-series data of the nutrients phosphate, silica, and nitrite+nitrate are used to verify model simulations and to calculate nutrient export budgets considering tidal and seasonal variations. The model results imply an export of nutrients from the tidal flats into the open waters of the German Bight which is in the same order of magnitude as the combined discharge of the rivers Elbe, Weser, and Ems. To investigate the importance of the Wadden Sea as a potential manganese source for the North Sea, transects were carried out into several tidal flat areas of the North Frisian Wadden Sea. The results suggest that the North Frisian Wadden Sea is a less important source for dissolved manganese compared to the East Frisian area. In contrary, the export of particulate manganese seems to be more important showing distinctly higher concentrations in the North Frisian study areas in summer. The influence of sediment permeability and bioturbation on trace metal budgets of the pore waters are investigated in natural and experimentally manipulated tidal flat sediments. Advective pore water transport in highly permeable sandy sediments and bioturbation promote exchange processes at the sediment/water interface probably leading to reduced nutrient and trace metal enrichments in the shallow pore waters. Furthermore, the penetration of oxygen into deeper sediment layers induces a release of sulphidic bound molybdenum to the pore water. During laboratory experiments with natural anoxic sediments an effective oxidative molybdenum release is determined during resuspension of the sediments in oxic seawater. Thus, pronounced sediment resuspension during storm events is suggested to cause significant release of molybdate from displaced anoxic sediment components thereby enhancing the molybdate level of the open water column. In addition to the examination of recent biogeochemical processes, the paleo-environmental influence on geochemical and microbiological processes in Holocene and Pleistocene sediments of the East Frisian study area were analysed in an interdisciplinary study. It is found that the microbial abundance and activity are higher in the Holocene than in the Pleistocene sediments. However, this is mainly caused by present environmental conditions. The impact of the paleo-environment on the microbiology is less pronounced. The lithological succession affects hydrological processes which enable the transfer of electron donors and acceptors for present early diagenetic processes into deep sediment layers. The paleo-environmental imprint is still detectable but the modern biogeochemical processes dominate in the sediment-pore water system.
In many industrial sectors biotechnological production processes have replaced pure chemical methods and allowed new, ecologically friendly and enzyme-based processes. Microorganisms, such as modified Bacillus strains are used in particular for the industrial enzyme synthesis. The two organisms Bacillus licheniformis and Bacillus pumilus are of great industrial importance. B. licheniformis is able to secrete proteins in large amounts, while B. pumilus shows high resistance to oxidative stress. During production processes different conditions can occur that affect the physiology of the production hosts and may result in a quantitative, but also a qualitative impairment of the products. This influence is based on e.g. chemical processes, the setting of temperature, pH, or oxygen availability and can lead to various stress situations for the bacteria. Cells respond to changes in their environment by sensing stressors and initiate a response to the stress, which is usually implemented by an induction or derepression of various regulons. In order to conduct an optimal production process, the metabolism and stress responses of the utilized bacteria should be known exactly. The aim of this study was to analyze of the stress response of B. licheniformis to heat and salt stress, and the stress response of B. licheniformis and B. pumilus to oxidative stress. These analyses were performed at the level of transcriptomics using cDNA microarrays, which is the most direct and global method for the analysis of changes in the physiology of a cell. The identification of stress specific markers genes and their differentiation from the SigB regulated general stress response has been another purpose of this work. Knowledge of these marker genes enables a prompt analysis of the fermentation conditions and thus a possible optimization of the process. The transcriptome analyses of this work show that B. licheniformis responds to heat stress by the induction of heat shock genes belonging to different regulons. These include the htpG gene, the HrcA regulon or the CtsR regulon, encoding chaperones and proteases, which mainly contribute to the protein quality control. The heat stress response of B. licheniformis revealed no fundamental differences to the heat stress response of the Gram-positive model organism Bacillus subtilis. The general stress response (SigB regulon), which is activated by heat stress, could be analyzed in more detail by the study of a ΔsigB mutant of B. licheniformis. Salt stress also provokes a strong induction of the general stress response in B. licheniformis. Genes for the transport and synthesis of compatible solutes were strongly induced, as well as several genes for transport systems with more or less known functions. The synthesis of the osmoprotective metabolites proline and glycine betaine could be verified in more detail by a metabolomics approach. The response to oxidative stress showed differences between both B. licheniformis and B. pumilus, and also to the oxidative stress response of B. subtilis. In B. licheniformis, the genes of the glyoxylate cycle are induced during oxidative stress. An activation of the glyoxylate bypass under oxidative conditions could be confirmed by a metabolome analysis of B. licheniformis. In addition, the PerR regulon of B. licheniformis is extended to include another two genes compared to B. subtilis. In contrast, several genes of the PerR regulon lack in the genome of B. pumilus, such as katA (vegetative catalase) or ahpCF (alkyl hydroperoxide reductase). However, other genes were induced in B. pumilus that were upregulated under oxidative stress conditions neither in B. subtilis nor in B. licheniformis. In addition, known regulons, regulated by e.g. Spx, CtsR or SOS were induced in both organisms. In summary, this dissertation transcriptionally analyzes the stress responses of B. licheniformis to heat, salt and oxidative stress, and in addition the oxidative stress response of B. pumilus. Several stress-specific regulons were identified in both, B. pumilus and B. licheniformis, which also correspond to the stress response of B. subtilis. However, it was possible to additionally assign genes to the stress specific responses of both organisms and to find differences, such as the absence of parts of the PerR regulon of B. pumilus, or the activation of the glyoxylate pathway in B. licheniformis during oxidative stress.
Compared to other human pathogens, S. aureus outstands with a remarkably broad spectrum of deseases: from minor skin infections over endocarditis, pneumoniae, and osteomyelitis, to septic shock. The prerequisite is an arsenal of adaptation strategies, encoded in the core and variable genome. It includes the coordinated expression of adhesins and toxins, evasion of the immune system, response to stress and starvation, adaptation of the metabolism, formation of biofilms and capsules, antibiotic resistance, and persistence on the skin, in nasal epithelial cells, and even in the inner of macrophages after phagocytosis. All these adaptation strategies enable S. aureus to colonize a diversity of niches within the human host. The inevitable requirement is the ability to activate the appropriate adaptation strategy at the right time and at the right place. S. aureus overcomes this challenge with a sophisticated regulatory network. This PhD thesis covers a broad spectrum of transcriptional regulators, involved in S. aureus pathogenesis: (1) the quorum sensing system Agr (regulation of early- and late stage virulence factors), (2) the Sar family (regulation of early- and late stage virulence factors), (3) SaeRS (regulation of accessory exotoxins and adhesins), (4) CodY (response to amino acid starvation, including extracellular proteases), (5) Sigma B (general stress response, including virulence factors), (6) Rex (anaerobic energy metabolism), (7) CtsR and HrcA (protein quality control), (8) PerR and Fur (oxidative stress response), and (9) antibiotic resistance. Traditionally, Proteomics constitute the long-lasting reputation of the Institute. In fact, the majority of investigations presented in this PhD thesis was initialized by proteomic analyses as the ultimate starting point. From the first day, a major goal of this PhD thesis was to add regulator-promoter interaction studies to the methodical spectrum. In particular, to complement transcriptomic and proteomic results by answering the logical follow-up question: Which regulator is responsible for the observed changes in gene expression and protein synthesis after application of a specific stimulus?
The first chapter provides specific analyses for three major regulators: Rex, CodY, and SarA. Publications were achieved for Rex (Hecker et al., 2009; Pagels et al., 2010). Results were mainly achieved by establishing regulator-promoter interaction methods (in particular EMSA and “footprinting”). Additionally, this chapter describes method development of a novel easy-to-apply method, named REPA (restriction endonuclease protection assay).
The second chapter presents method development for the genome-wide identification of regulator-promoter interactions, named “global footprinting”. This approach combines two already well-established methods: (A) Purification of a recombinant Strep-tagged regulator via Strep-tag affinity chromatography. The modification in “global footprinting” is to incubate the regulator with fragmented genomic S. aureus DNA, resulting in co-purification and enrichment of DNA streches with specific regulator binding sites. (B) Identification and quantification of these DNA streches via “next generation sequencing” (NGS). Using this combined approach, this PhD thesis was able to localize the most affine promoter binding site for the regulator Rex precisely down to one single base pair across the whole S. aureus genome.
The third chapter describes the assembly of a data library, collecting the majority of DNA microarray data and regulator-promoter interaction studies from the worldwide literature. This data library summarizes more than 50,000 regulatory events and more than 2,000 regulator binding sites. As published in the perspectives in Fuchs et al. (2018), this data library can be incorporated into the free-accessible online data base “Aureowiki” (provided and maintained by the Department of Functional Genomics, University of Greifswald). The major effort is the consolidation of these “big data” via in silico cluster analysis, comparing 282 different experimental conditions at once. The major finding of this analysis is the identification of seven functional and regulatory gene clusters in S. aureus pathogenesis that are conserved across S. aureus strain diversity. These findings allowed the creation of a prediction tool, to provide novel experimental starting points for the worldwide S. aureus research community. This prediction tool was successfully applied on several topics, and partially published: functional and regulatory prediction for a set of 20 selected lipoproteins as potential virulence factors (Graf et al., 2018), and prediciton of protein complexes (Liang et al., 2016).
Alltogether, this PhD thesis provides new insights into the molecular mechanisms of three pathogenesis-relevant regulators: Rex, CodY, and SarA. It describes the development of three novel experimental methods for wet and dry lab applications that can be used on research topics beyond S. aureus: REPA, “global footprinting”, and cluster analysis. Finally, cluster analysis identifies seven conserved fuctional and regulatory gene clusters, involved in S. aureus pathogenesis. This cluster anaysis is used as a prediction tool to provide novel experimental starting points, and to predict the physiological mode of action of newly discovered anti-staphylococcal agents.
This thesis aims to investigate effects of anthropogenic environmental impact on the Richards Bay area. Located on the east coast of South Africa, Richards Bay Harbour evolved into the country’s premier bulk cargo port. The Associated change in land-use and industrial as well as agricultural pollution pose environmental, ecological and human health risks. Here, sedimentological and geochemical investigations focus on the port as final sink for environmental and industrial pollutants, such as metal concentrations, organochlorine pesticides and microplastics.
The study is based on investigations of surface sediment samples from the water-sediment interface to identify spatial distribution patterns, as well as sediment cores to follow temporal changes. Endmember modelling of grainsize distributions, proved to be a viable parameter to distinguish different accumulation spaces and enabled the classification into six harbour sub-basins. Subsequent investigations on the content of microplastics, Polyethylene terephthalate (PET) and Low-density polyethylene (LDPE), showed that these different types of microplastics predominate in two different areas: PET appears to be directly tied to higher populated (tourism) beaches, while LDPE is deposited in low-current sub-basins. Increased metal concentrations link to activities at the bulk cargo berths, where especially Cr and Cu concentrations exceeded the local sediment guideline thresholds. In the areas of high metal concentrations, bioindicators (ostracods, foraminiferas, diatoms) also indicate increased shares of malformed specimens. Multiple recovered sediment cores recorded changes in recent export practices, indicating ceased Cu handling and increased Cr handling over the past decade. Noticing multiple possible influencing factors on elemental distributions, created by the surrounding geological and industrial impact, the usefulness of different normalisers (Al, Fe, Rb, Ti and silt fraction) for Cr, Cu, Co and Pb concentrations was compared and site specific baseline metal concentrations were defined. This identified Al and Rb to be effective normalisers in Richards Bay and Fe or Ti to be affected by local conditions. Data of organochlorine pesticide pollution was gathered in the area of Richards Bay, Goedertrouw Dam and Umlalazi River. The two dominant groups of contaminants detected are dichlorodiphenyltrichloroethanes (ΣDDT, 12 – 350 ng g-1), linked to the use of malaria vector control, and hexachlorocyclohexanes (ΣHCH 35 – 230 ng g-1), an agricultural insecticide. Both indicate recent entry and exceed sediment quality guideline limits, raising concern for local communities and estuarine environments. Seismic data was used to investigate the preindustrial evolution of the incised valley system and bayhead delta at Richards Bay Harbour. A stratigraphically supported development model was created. The thesis shows that harbour sediment is an important sink for inorganic and organic contaminants. Each investigation on environmental pollutants, such as metals, pesticides, microplastics or bioindicator analyses, indicates their deposition in distinct harbour sub-basins. Therefore, their effect can be spatially differentiated and related to plausible sources of pollution. Richards Bay thus represents a variously affected system along the South African coast, in which it is necessary to take environmental protection measures in terms of sustainable and environmentally friendly management.
To enable control of African swine fever (ASF) in Eastern and Southern Africa, prototype live vaccine candidates were generated by targeted gene deletions from a Kenyan genotype IX ASF virus (ASFV). It was attempted to delete known nonessential genes involved in virulence (encoding TK, dUTPase, CD2v, 9GL), possibly essential genes (p12, pA104R, ribonucleotide reductase), and genes with widely unknown functions (pK145R). Isolation of the desired virus recombinants by plaque assays or limiting dilutions on a wild boar lung cell line (WSL-HP) was facilitated by substitutive reporter gene insertions encoding fluorescent proteins (GFP, DsRed), or the human membrane protein CD4. The latter protein permitted enrichment of recombinant virus particles by magnetic activated cell sorting (MACS). The isolated ASFV recombinants were characterized by PCR and sequencing of the mutated genome parts, and replication kinetics and virus spread in cell culture were investigated. Deletion of TK, CD2v, or pK145R had no detectable effect on in vitro growth of ASFV Kenya. Interestingly, virus mutants lacking the DNA binding protein pA104R which has been considered to be essential for DNA replication, also exhibited almost wild type-like growth properties.
In contrast, ASFV mutants lacking ribonucleotide reductase or p12 could not be purified to homogeneity on WSL-HP cells, indicating these proteins are essential for virus replication in cell culture. Therefore, trans-complementing cells lines stably expressing ASFV p12 have been prepared which can now be used for mutant virus purification. If this approach is successful the resulting defective mutant ASFV Kenya-p12 might be suitable as a safe “disabled in second cycle” (DISC) live vaccine in swine.
In a novel approach to improve reverse genetics of ASFV the CRISPR/Cas9 cell line WSL-gRp30 (Hübner et al., 2018a) was co-transfected with genomic DNA of ASFV-KenyaCD2vDsRed, sgRNA plasmids targeting K145R or 9GL, and GFP-expressing recombination plasmids for homology-directed repair. For booting up of the noninfectious virus genome the cells were infected with phylogenetically distant helper virus (genotype II ASFV Armenia, 84% identity) which was selectively inhibited on the used cell line. The desired double-fluorescent double-deletion mutants could be isolated after few plaque purification steps on selective WSL-gRp30 cells. Next generation sequence (NGS) analyses of reconstituted ASFV Kenya genomes showed that no unwanted recombination with the helper virus occurred, indicating that the method might be also suitable for booting of synthetic ASFV genomes cloned and mutagenized in E. coli or yeast.
The modified CRISPR/Cas9 system of S. pyogenes might be also usable for generation of ASFV resistant pigs. To evaluate this alternative control measure WSL cell clones stably expressing Cas9 nuclease and single or multiple sgRNAs against essential ASFV proteins were prepared and tested for their susceptibility to infection. Strain specific sgRNAs targeting the p30 gene of ASFV Kenya or Armenia selectively inhibited the respective viruses, and a p12 gene-specific sgRNA abrogated replication of both genotypes almost completely. Interestingly, coexpression of four ASFV-specific sgRNAs did not enhance virus inhibition, but might help to reduce the frequency of escape mutants which were occasionally isolated from the single sgRNA-expressing cells, and exhibited silent base substitutions or in-frame deletions within the target genes. First attempts to express the in vitro tested CRISPR/Cas9 constructs in transgenic pigs are in progress.
CRISPR/Cas9 supported rescue of a defective BAC clone of pseudorabies virus (PrV) vaccine strain Bartha (Hübner et al., 2018b) was used to develop putative vectored vaccines against ASFV. In the present study expression cassettes for the codon-optimized p12 and p54 genes of ASFV were successfully inserted into the PrV genome. The insertions did not significantly affect PrV recombination in cell culture, and the transgenes were expressed at similar levels as in ASFV-infected cells. It has to be tested whether coinfection with vector constructs for these and other immunogenic ASFV proteins is able to protect pigs against a lethal challenge.
For characterization of the generated ASFV mutants and PrV vector constructs, monospecific antisera against several ASFV gene products (p11.5, p12, p54, pK145R, p285L) were prepared by immunization of rabbits with bacterial GST fusion proteins. The anti-p12 serum showed only weak and strain-specific reactions with the ASFV Kenya protein, but was nevertheless useful for identification of p12-expressing PrV recombinants and WSL cell lines. All other sera showed satisfying reactions in Western blot and mostly immunofluorescence analyses, and allowed i.a. precise localization of the pK145R and p285L proteins in ASFV-infected cells and virions (Hübner et al., 2019).
This work first sets out to find if economic, ecological, or social incentives drive consumers towards or against dietary decisions (Contribution A). It then develops a framework of TCA for food to describe economically conveyed incentives that are tied to ecological and social indicators within the food market (Contribution B). The framework is subsequently enhanced and broadened to include a deeper understanding and broader field of indicators for more holistic TCA calculations (Contributions C and D). Lastly, based on these calculations, TCA of food is implemented in a factual use case as the framework and calculations are deployed for commodities of a German supermarket chain; then consumer, as well as expert feedback is used for the discussion on socially responsible campaigning and policy change (Contribution E).
Foot-and-mouth disease virus (FMDV) is a positive-sense RNA virus of the family Picornaviridae that comprises of seven serotypes and is distinguished by a high contagiosity with the ability of rapid spread. Strategies for abatement and control are based on an early detection, quick initiation of retaliatory actions and mass vaccinations. Therefore, aim of the study was the development of a fast and easy method for genome sequencing as well as an investigation into the causes, why some cell lines that are mainly used for vaccine production, are resistant towards FMDV infection. Finally, adaptive sequence changes in different cell culture systems and associated effects on particle stability and immunogenicity were examined.
In case of an outbreak it is of major importance to detect and rapidly characterize the circulating virus isolate to choose an appropriate vaccine to minimize the viral spread. In addition, comprehensive genome analysis of the outbreak strain provides information about the origin of the virus and allows molecular epidemiology. A universal primer set, covering most parts of the open reading frame of the viral genome, was developed to perform quick sequence analyses, independently of the viral serotype (Paper I). Especially in endemic regions, vaccination of susceptible animal species is the main action to combat foot-and-mouth disease (FMD) in an acute outbreak situation as well as a preventive measure. Reasons, why some baby hamster kidney (BHK) cell lines are resistant towards an infection with FMDV, were examined in a second study that narrowed down the cause for this phenomenon to an impaired attachment of the virus to the cell surface. Furthermore, an alternative approach could be developed to successfully adapt the virus to the resistant vaccine-production cell line by using a FMDV-sensitive “wet-nurse” cell line (Paper II). Adaptive changes in the capsid-coding region of the viral genome caused through cultivation and passaging of the virus in different BHK cell systems were the topics of the third study. It was shown that capsid alterations are rather serotype-specific and dependent on the cell line used than influenced by the cell media. Viral titers and neutralization profiles of the adapted isolates were not affected compared to the original viruses (Paper III).
Overall, this work expanded our knowledge on the control and eradication of FMD and will support the global effort to combat the disease.
Experience in the construction of optimized stellarators shows the coil system is a significant challenge. The precision necessary allow the generation of accurate flux surfaces in recent experiments affected both cost and schedule negatively. Moreover, recent experiments at Wendelstein 7-X have shown that small field corrections were necessary for the operation of specific desired magnetic configurations. Therefore, robust magnetic configurations in terms of coil geometry and assembly tolerances have a high potential to facilitate swifter and less expensive construction of future, optimized stellarators. We present a new coil optimization technique that is designed to seek out coil configurations that are resilient against 3D coil displacements. This stochastic version of stellarator coil optimization uses the sampling average approach to incorporate an iterative perturbation analysis into the optimization routine. The result is a robust magnetic configuration that simultaneously reproduces the target magnetic field more accurately and leads to a better fusion performing coil configuration.
Although the Pleistocene deposits exposed in the steep coastal cliffs of Mecklenburg-Vorpommern have been studied for more than a century, the depositional conditions of many lithostratigraphic units remain unclear. There is, in particular, a question whether the individual tills (locally more than 9 successive till units) are mainly subglacial deposits or resedimented (mass flows) in origin (at least in part). The Pleistocene deposits preserve information concerning the former glacial depositional processes. Detailed micromorphological analysis of these deposits can provide key information regarding these processes and thereby aid in the reconstruction of former glacial environments. The island of Rügen is located on the southwestern Baltic Sea coast and was situated in the marginal zone of the Scandinavian Ice Sheet during the last glacial period (Weichselian). Therefore, the region is considered as an ideal area for reconstructing the complex fluctuations in the position of the margin of this ice sheet as it expanded across the Baltic Sea and into northern Germany. Successive glacial advances and retreats of the ice sheet can be reconstructed by specific glacial sedimentation processes and flow-direction criteria derived from a variety of glacial deposits. The investigation area is located near Sassnitz on Rügen, where an imbricated and folded Weichselian succession disconformably overlies Maastrichtian chalk bedrock. The individual till units were sampled for micromorphological analyses to identify the former depositional conditions. Detailed description of the sedimentology and variation in facies, the description of macroscale deformation structures provides the context for the detailed micromorphology study. The three dimensional analysis of the microfabrics is based on the microstructural mapping methodology which enables the identification and interpretation of polyphase deformation within subglacial sediments.
This thesis is devoted to experiments on three-dimensional dust clouds which are confined in low temperature plasmas. Such ensembles of highly electrically charged micrometer-sized particles reveal fascinating physics, such as self-excited density waves and vortices. At the same time, these systems are challenging for experimental approaches due to their three-dimensional character. In this thesis, new optical diagnostics for dusty plasmas have been developed and, in combination with existing techniques, have been used to study these 3D dusty plasmas on different size and time scales.
The deep geological underground represents an important georesource for the short-
term storage of renewable energy and the long-term reduction of greenhouse gas emissions. To ensure the economic viability and safety of any subsurface storage project, detailed characterisation of the quality and integrity of the reservoir and its cap rock is required. This characterisation includes the accurate determination of the petrophysical properties, such as porosity and permeability, as well as the potential mineral reactions, such as the dissolution of reactive phases, which may occur during the lifespan of such a project. Clay minerals are common components of many reservoir systems and, depending on their type and structure, can have a significant impact on storage and transport properties. These processes are, however, currently not well understood. In order to address these issues, the main focus of this thesis is on mineralogical analyses using X-ray diffraction (XRD) and microstructural studies using focused ion beam scanning electron microscopy (FIB-SEM) together with micro X-ray computed tomography (µXCT) to gain a better understanding of the influence of clay minerals on reservoir and cap rock properties.
A central part of this thesis focuses on the analysis of clay minerals and pore structures of the Bebertal Sandstone of the Parchim Formation (Early Permian, Upper Rotliegend), which is considered a natural analogue for the tight reservoir sandstones of the North German Basin. Two illite polytypes with a variety of characteristic structures have been identified in the Bebertal sandstone. Disordered 1Md illite forms the majority of the observed structures, which include omnipresent grain coatings, altered permeable feldspar grains and pore-filling meshwork structures. Trans-vacant 1M illite represents the second and youngest generation of authigenic illite and occurs as fibrous to lath-shaped particles that grew into open pore spaces and led to a significant reduction in porosity and permeability during late diagenesis. Based on these results, a model for the formation of illite polytypes in the aeolian layers of the Bebertal sandstone was developed that describes the temporal and spatial evolution of porosity and permeability during diagenesis. Information from this model was then used to improve the prediction of permeability of the Bebertal sandstone based on µXCT pore space models and direct numerical simulations. To achieve this, a micro-scale pore space model was created that allowed the simulation of permeability reduction by clay minerals by including nanoporous illite domains based on a novel morphological algorithm. By performing Navier-Stokes-Brinkman simulations, more accurate predictions of permeabilities with respect to experimentally determined values were obtained compared to conventional Navier-Stokes simulations.
The detailed characterisation of the Bebertal sandstone has shown that natural reservoir rocks are usually complex heterogeneous systems with small-scale variations in texture,
composition, porosity and permeability. Flow-through experiments on the Bebertal sandstone revealed that the coupled geochemical and hydrodynamic processes that occur during the dissolution of calcite could not be predicted by reactive transport models. Therefore, as part of this thesis, a novel approach for developing synthetic sandstones at low temperatures based on geopolymer binder was developed. It is shown that simpler and more homogeneous porous materials can be produced with porosity and permeability values in the range of natural sandstones. These can be used to better understand the dynamic and coupled processes relevant to the storage of renewable energy in reservoir rocks through improved experimental constraints.
The final part of this thesis reports on a detailed clay mineral and pore space study of
three shale formations and one mudstone that were identified as potential seals for the Mt. Simon sandstone reservoir in the Illinois Basin. During the Illinois Basin - Decatur Project, this reservoir was used for the sequestration of one megaton of supercritical carbon dioxide. In order to better assess the quality of the sealing units and to better understand the role of the intergranular clay mineral matrix as potential pathway for fluid migration, a multi-scale evaluation was conducted that included thin section analysis, quantitative evaluation of minerals by scanning electron microscopy (QEMSCAN), mercury intrusion capillary pressure (MICP) measurements, quantitative XRD and high-resolution FIB-SEM. The results allow for the classification of the studied formations into primary and secondary seals and emphasise the importance of three-dimensional clay-mineral-related pore structure characterisations in cap rock studies. XRD proved the most reliable method for the identification and quantification of clay minerals in the studied cap rocks and mudstones. In contrast, FIB-SEM and QEMSCAN provided the spacial constraints for reconstructing fluid flow pathways within the clay mineral matrix.
Overall, this thesis highlights the importance of the precise identification of clay minerals in geological reservoirs and their cap rocks. It also illustrates the need for three-dimensional characterisation and modelling of the associated small pore structures for an improved understanding of the rocks diagenetic history as well as the prediction of the transport and storage properties of these crustal reservoir systems.
Body sensations play a crucial role in the etiology and maintenance of diverse anxiety and health problems (e.g., in panic disorder or respiratory diseases) as they may be perceived as threatening and consequently elicit anxious responses. The factors that may affect the perception of bodily sensations as a threat and thus modulate the anxious response to body sensations have so far rarely been studied. Therefore, the present thesis targeted at elucidating the effect of contextual (i.e., the predictability, expectation, and proximity of a threat) and dispositional factors (i.e., tendency to fear arousal sensations or trait fear of suffocation) on the defensive response to body sensations.
In study 1, it was investigated how a personality factor, that is, fear of suffocation, affects the acquisition of fear to body sensations (i.e., mild dyspnea induced by inspiratory resistive loads) and contexts when faced with a predictable and unpredictable respiratory threat (i.e., severe dyspnea). Study 2 aimed at examining the main and interactive effects of the tendency to fear arousal sensations, again a personality trait factor, and current arousal expectations as varied by situational variables on anxious responding to arousal sensations. In this study, expected and unexpected arousal sensations were induced by administering caffeine in coffee or bitter lemon soda, respectively. Moreover, in study 3, it was explored how subjective anxiety, bodily symptoms, and defensive respiratory responses change and might culminate into active defense behavior (i.e., escape/active avoidance) during increasing dyspnea that was evoked by inspiratory resistive loads increasing in intensity. For a detailed analysis of the factors that contribute to the initiation and maintenance of avoidance of or escape from increasing dyspnea, in study 4 changes in subjective, autonomic, somatic reflex and brain responses were analyzed during repeated avoidance of increasing dyspnea.
In study 1, it was demonstrated that only individuals who fear suffocation learned to fear mild dyspnea preceding the onset of severe dyspnea and developed anxiety during a context of unpredictable respiratory threat. Moreover, the data from study 2 indicate that individuals who fear arousal sensations show an increased attention allocation towards unexpected arousal sensations and higher threat appraisal when expecting arousal sensations. Increasing intensity of dyspnea as provoked in study 3 led to increased defensive respiratory responses that were associated with increased symptom reports in individuals with high compared to low fear of suffocation. Moreover, culminating dyspnea elicited repeated avoidance behavior preceded by increases in defensive respiratory mobilization. The analysis of repeated avoidance of increasing dyspnea in study 4 revealed that physiological fear responses might be involved in the initial initiation of this avoidance behavior while no indication of response preparation and physiological arousal was related to persistent avoidance.
Taken together, the present data suggest that the fear of suffocation, as well as the tendency to fear arousal sensations along with the predictability, expectation, or proximity of interoceptive threat, may increase the perceived threat and thus the anxious response to body sensations. Therefore, contextual and dispositional factors may set the stage for the culmination of body sensations into defensive action and might contribute to the development of pathological anxiety and fear of body sensations. The present findings are integrated into the current literature and discussed in relation to the development and maintenance of pathological anxiety and fear of body sensations.
To what extent do norms of regional Intergovernmental Organizations (IGOs) have an impact on member states’ borders and their permeability? International agreements and regional integration measures quite often highlight how harmonization of mechanisms and procedures related to cross-border interaction within specific communities takes place. As these agreements and measures contain mutual expectations about appropriate behavior, a form of convergence in bordering practices – and therefore effects – is implied. This leads to the assumption that cross-border interaction is gradually increasing and eventually leading to a ‘borderless’ realm that allows for the free movement of goods, services, persons, and capital. However, the nature of borders or a deeper understanding of the bordering process itself is often not central to the studies of international relations. They represent mere fixtures of international interaction and appear in the public discussion only if sudden restrictions are implemented or if large-scale changes in the international environment affect their functioning.
Specific literature on borders is relatively new and located mainly within an interdisciplinary setting that largely lacks coherency in its ontological concepts or deals exclusively with individual cases. The literature on the normative capacity of (regional) IGOs on the other hand is well matured and one of the cornerstones of international studies. However, here a blatant neglect of borders and bordering is apparent. This situation is aggravated by the circumstance that the field of International Relations by definition is dealing with cross-border interaction.
Apart from the general ontological issue of what borders and bordering processes are from a political science perspective, three main gaps in conjunction with the above question could be identified within the literature. The first relates to the general efficacy of the normative influence of regional IGOs on enhancing cross-border interaction through the issuing of specific normative provisions. On this, the relevant literature is divided. Arguments range from an all-permeating relevance of norms as intersubjective understandings that create specific expectations of appropriate behavior to the primacy of rational choices that are targeted to create benefits in most economic and security- related matters. The second gap relates to the relevance of domestic precognition in cross-border interaction. It is not clear to what extent dominant normative conceptions at the national level create obstacles to the efficacy of IGO provisions in shaping cross- border interaction. Finally, the impact of critical junctures – as kind of catalysts – that shift member state preferences in following communal obligations are being analyzed. Here, the assumption is that these junctures may either enhance or negate IGO provisions dependent on the dominant domestic preferences. Essentially, the approach taken here is a layered one, where each identified gap provides the basis for the following ones. The analysis itself is divided into a quantitative and a qualitative part. For the former, a new dataset has been created that specifically lists all normative provisions targeting the free movement of goods, services, persons, and capital of the two IGOs selected for this research project. This is an important departure from the usual dichotomous perception of IGO influence used throughout the literature. In conjunction with specific data related to each of the four freedoms, multiple variations of a gravimetric Poisson Pseudo-Maximum Likelihood model are specified. The qualitative approach draws upon descriptive and matching approaches to analyze the impact of dominant domestic norms and critical junctures on the bordering process. For this purpose, a corpus of source material is created that includes government declarations and media articles, as well as the specific IGO provisions on bordering to each of the four freedoms that are central to this research.
The quantitative findings indicate a strong and consistently positive impact of regulative IGO norms while evaluative IGO norms do not provide similar results. The qualitative findings point in a similar direction. As long as IGO norms have a more regulative direction and are obligatory, the effect is less likely to be diminished by contesting dominant domestic norms or critical junctures vis-`a-vis more evaluative IGO norms.
The results and additional findings of this research have implications for further research. Central to this is the capacity of regional IGOs to exert normative influence on the bordering practices of their member states. An additional finding relates to the interrelatedness of normative provisions. The more these provisions are cross-referencing each other – or are interlocked – the more robust they seem to get. This is a trait that is relevant for policy-makers and IGO bureaucracies if they want to enhance the compliance of their agents. On a methodological level, the here introduced data set on normative IGO provisions provides other researchers with a substantially more fine- grained approach to investigating the impact of specific IGO measures on a particular dimension of cross-border interaction.
Objectives: To examine the association between third molars and orofacial pain. We hypothesized that impacted third molars are a cause of orofacial pain.
Methods: Magnetic resonance images of 1808 participants from two populationbased cohorts from Northeastern Germany were analysed to define the status of third molars according to the Pell and Gregory classification. A self-reported questionnaire and a clinical dental examination were used to detect chronic and acute complaints of orofacial pain, masticatory muscle pain, migraine and other types of headache. Logistic regression models were used to analyse the associations between third molar status and orofacial pain.
Results: Individuals with impacted third molars in the maxilla had a higher chance of chronic orofacial pain than those with erupted third molars (odds ratio 2.19; 95% CI 1.19-4.02). No such association was detected for third molars in the lower jaw. Third molars were not associated with masticatory muscle pain, migraine or other types of headache.
Conclusions: Impacted maxillary third molars might be a cause of chronic orofacial pain. Thus, physicians should consider the eruption/impaction status of third molars in their decision-making process when treating patients who complain of orofacial pain.
Bacteria are exposed to oxidative stress as an unavoidable consequence of their aerobic lifestyle. Reactive oxygen species (ROS) are generated in the stepwise one-electron reduction of molecular oxygen during the respiration. Pathogens encounter ROS during the oxidative burst of macrophages as part of the host immune defense. Besides ROS, bacteria also have to cope with reactive chlorine, electrophilic and nitrogen species (RCS, RES, RNS). To cope with these reactive species, bacteria have evolved different defense and repair mechanisms. To maintain the reduced state of the cytoplasm, they utilize low molecular weight (LMW) thiols. LMW thiols are small thiol-containing compounds that can undergo post-translational thiolmodifications with protein thiols, termed as S-thiolations. S-thiolations function as major redox regulatory and thiol-protection mechanism under oxidative stress conditions. In eukaryotes and Gram-negative bacteria, the tripeptide glutathione (GSH) functions as major LMW thiol, which is present in millimolar concentrations. The Actinomycetes, such as Mycobacterium and Corynebacterium species do not produce GSH and utilize instead mycothiol (MSH) as their alternative LMW thiol. In Firmicutes, including Bacillus and Staphylococcus species, bacillithiol (BSH) functions as the major LMW thiol. LMW thiols protect protein thiols against the irreversible overoxidation of cystein residues to sulfinic and sulfonic acids. In addition, LMW thiols contribute to the virulence and survival of pathogens, function in metal homeostasis and serve as enzyme cofactors for detoxification of xenobiotics and antibiotics. In this doctoral thesis, we aimed to investigate the roles of MSH and BSH in redox regulation of main metabolic enzymes under oxidative stress in the pathogens Corynebacterium diphtheriae and Staphylococcus aureus. Previous redox proteomics studies identified the glyceraldehyde-3-phosphate dehydrogenase GapDH and the aldehyde dehydrogenase AldA as S-thiolated in S. aureus and C. diphtheriae. Thus, we aimed to study the redox regulation of the metabolic enzyme GapDH in C. diphtheriae in response to NaOCl and H2O2 stress by S-mycothiolation, which is described in chapter 1. Moreover, we studied the involvement of the mycoredoxin-1 (Mrx1) and thioredoxin (Trx) pathways in reactivation of S-mycothiolated GapDH in vitro. Using shotgun proteomics, 26 S-mycothiolated proteins were identified under NaOCl stress in C. diphtheriae. These are involved in energy metabolism (Ndh, GlpD) and in the biosynthesis of amino acids (ThrA, LeuB), purines (PurA) and cell wall metabolites (GlmS). The glycolytic GapDH was identified as conserved target for S-thiolation across Gram-positive bacteria. GapDH was the most abundant protein, contributing with 0.75 % to the total cystein proteome. Moreover, GapDH is a conserved target for redox regulation and S-glutathionylation in response to oxidative stress in several prokaryotic and eukaryotic organisms. Treatment of GapDH with NaOCl and H2O2 in the absence of MSH resulted in irreversible enzyme inactivation due to overoxidation. Pretreatment of GapDH with MSH prior to H2O2 or NaOCl exposure resulted in reversible inactivation due to S-mycothiolation of the active site Cys153. Since S-mycothiolation is faster compared to overoxidation, S-mycothiolation efficiently protects the GapDH active site against overoxidation. The activity of S-mycothiolated GapDH could be restored by both, the Mrx1 and Trx pathway in vitro. Interestingly, the recovery of Smycothiolated GapDH by Mrx1 was faster compared to its reduction by the Trx pathway. In previous studies, the reactivation of S-mycothiolated Mpx and MrsA by the mycoredoxin pathway occurred also faster compared to the Trx pathway, which is consistent with our results. We were further interested to analyze the redox regulation of the glyceraldehyde-3phosphate dehydrogenase Gap of S. aureus under NaOCl and H2O2 stress, which is described in chapter 2. Using the quantitative redox proteomic approach OxICAT, 58 NaOCl-sensitive cystein residues with >10% thiol oxidation under NaOCl stress were identified. Gap and AldA showed the highest oxidation increase of 29% under NaOCl stress at their active site cystein residues. Using shotgun proteomics, five S-bacillithiolated proteins were identified, including Gap, AldA, GuaB, RpmJ and PpaC. Gap contributed with 4 % as most abundant cystein protein to the total cystein proteome. Our activity assays demonstrated that Gap of S. aureus is highly sensitive to overoxidation by H2O2 and NaOCl in vitro in the absence of BSH. The active site Cys151 of Gap was oxidized to the BSH mixed disulfide under H2O2 and NaOCl stress in the presence of BSH in vitro, which resulted in the reversible Gap inactivation. Moreover, inactivation of Gap by NaOCl and H2O2 due to S-bacillithiolation was faster compared to overoxidation, indicating that S-bacillithiolation protects the Gap active site against overoxidation in vitro. We further showed that the bacilliredoxin Brx catalyzes the reduction of S-bacillithiolated Gap in vitro. Molecular docking of BSH into the Gap active site revealed that S-bacillithiolation does not require major structural changes. Apart from Gap, the aldehyde dehydrogenase AldA was identified as S-bacillithiolated at its active site Cys279 under NaOCl stress in S. aureus previously. Thus, the expression, function, redox regulation and structural changes of AldA were analysed under NaOCl and aldehyde stress in S. aureus as summarized in chapter 3. AldA was S-bacillithiolated in the presence of H2O2 and BSH as demonstrated in BSH-specific Western blots in vitro. The expression of aldA was previously shown to be regulated by the alternative sigma factor SigmaB in S. aureus. Transcription of aldA was strongly increased in a SigmaB-independent manner under formaldehyde, NaOCl and diamide stress in S. aureus. Using an aldA deletion mutant, we demonstrated that aldA is required for growth and survival under NaOCl stress in S. aureus. The purified AldA enzyme was shown to catalyze the oxidation of various aldehyde substrates, including formaldehyde, methylglyoxal, glycolaldehyde and acetaldehyde in vitro. In addition, the function of the conserved Cys279 for AldA activity was investigated in vivo and in vitro. The purified AldAC279S mutant was shown to be inactive for aldehyde oxidation in vitro. Moreover, the aldAC279S mutant was very sensitive under NaOCl stress in vivo, and this phenotype could be reversed using the aldA complemented strain. These experiments demonstrate the function of Cys279 for AldA activity both in vitro and in vivo. AldA activity assays showed that AldA is sensitive to overoxidation and irreversible inactivation by H2O2 alone in vitro. In the presence of BSH, AldA is protected against overoxidation by reversible Sbacillithiolation in vitro. Molecular docking and molecular dynamics simulations revealed that BSH occupies two different positions in the Cys279 active site, which depend on the NAD+ cofactor. In the apoenzyme, BSH forms the disulfide with Cys279 in the “resting” state position, while Cys279 is S-bacillithiolated in the “attacking” state position in the holoenzyme in the presence of the NAD+ cofactor.
The present work is a cumulative dissertation that covers the research work of the author at the Department of Analytical and Physical Chemistry of Chelyabinsk State University. It contains a short description of the study and a set of attached publications in peer-reviewed journals and conference proceedings.
The phase and chemical equilibria in binary systems Me – Si
(where Me is the 4th-period transition metal) as well as Mo – Si, Mn – Ge and Fe – Ge at low temperatures were considered. The solid solubility of silicon in vanadium, chromium, manganese, iron, nickel, cobalt and copper and that of germanium in manganese and iron was estimated.
The phase equilibria in Me – Si – O, Mo – Si – O, Mn – Ge – O and Fe – Ge – O ternary systems at standard conditions were considered from a thermodynamic viewpoint. The atmospheric corrosion of transition metals silicides and manganese and iron germanides was discussed.
The chemical and electrochemical equilibria in Me – Si – H2O, Mo – Si – H2O, Mn – Ge – H2O and Fe – Ge – H2O systems were considered from a thermodynamic viewpoint. Pourbaix diagrams for some 4th-period transition metals and molybdenum, as well as for silicon, were revised. The potential – pH diagrams for Me – Si – H2O, Mo – Si – H2O, Mn – Ge – H2O and Fe – Ge – H2O systems were plotted in the first time. The corrosion-electrochemical behaviour of transition metals silicides and manganese and iron germanides in aqueous media was discussed.
The potential – pH diagrams for some siliceous brasses and bronzes (which are multicomponent alloys containing both transition metals and silicon) were plotted, and the corrosion of these alloys in aqueous media was discussed.
Method of estimation of corrosion-electrochemical behaviour of multicomponent alloys, which takes into account both thermodynamic and kinetic data and is based on mutual construction of equilibrium and polarisation potential – pH diagrams, was described. Its usage was illustrated in the example of the structural steel 20KT.
In this thesis, I was able to provide answers to transport processes in lipid monolayers, which are ultimately, all of biological relevance. In particular, I was interested in lipid oxidation and dynamic compression/expansion processes of surfactant monolayers at the air-water interface:
Lipid oxidation was shown to be a consequence of the formation of a high concentration of reactive oxygen species (ROS) during cell respiration, which finally can lead to severe cell damage. It is not yet understood clearly, which part of the lipid molecules is especially prone to a ROS attack. I was particularly interested in the role of the double bonds of the acyl chains of the lipid molecules during oxidation. Further, I wanted to know the time scales of lipid interaction with the ROS.
Compared to lipid vesicles, lipid monolayers have the advantage that many parameters of the system can be adjusted easily. In our system, I made use of this by setting the lateral pressure to low values during H2O2 treatment, which facilitated the ROS to reach the double bonds in the acyl chains.
A prime example of biological systems out of thermal equilibrium was given in the alveolus surface, which is covered with a surfactant monolayer. During breathing, these monolayers undergo such a highly dynamic compression and expansion. Arising flows from breathing could disrupt a film and consequently, it would lose its protective role. One of my goals was to understand flows and their influence on domain shape. Dependent on the strength of the flows, I expected different growth regimes, with differing prevailing transport processes. Once understanding the underlying mechanisms in domain shaping would allow me to draw conclusions on biological systems.
In order to address these questions, I established two systems, both based on the compression of lipid monolayers. I used isotherms to study the phase behavior of the lipids:9 During compression, the lipids can undergo phase transitions from the gaseous phase to the liquid expanded phase (LE-phase) and further from the LE-phase to the liquid condensed phase (LC-phase). A coexistence regime is observed in between the LE-phase and the LC-phase, characterized by a flat increase of lateral pressure with decreasing molecular area. Some lipids exhibited LC-phase domains. These were further investigated with Brewster angle microscopy (BAM). The used BAM was equipped with an integrated Scheimpflug optics, enabling an overall focused image plane. Furthermore, time-resolved observation of the growth of the domains was possible by recording videos (20 frames per seconds).
The first system enabled the investigation of lipid peroxidation, when the lipids were exposed to ROS. I chose DMPC, POPC, DOPC and PLPC, since these are phospholipids differing in the number and position of double bonds in acyl chains, but not in the head group. I used a H2O2 enriched phosphate buffered saline (PBS) solution, which served as a precursor for more reactive ROS, like hydroxyls (.OH). PBS was chosen, since it resembles the cell environment best. During defined waiting times of H2O2 treatment, the ROS diffused vertically from the subphase towards the monolayer. The lipid molecules were in the LE-phase, which facilitated the ROS molecules to reach also the double bonds of the acyl chains. The oxidized monolayers were then compressed at constant compression speed. Since the corresponding isotherms could be measured with high precision, the relative area increase δA/A between oxidized and non-oxidized monolayer along the isotherm proved to be a good measure for lipid peroxidation. The area increase δA in the molecular area of the oxidized molecules was explained by the eventually added, more hydrophilic −OOH group at the position of a carbon atom adjacent to a double bond in the unsaturated acyl chain. The −OOH group is drawn to the hydrophilic head group of the lipid. This leads to a kink in the acyl chain, which increases the molecular area A by δA. A model, which explained this peroxidation process in lipid vesicles, could be adopted to monolayers.
I compared the oxidation of phospholipids, differing in the number and position of the double bonds of their acyl chains. I found that δA/A increased with the growing number of double bonds in one acyl chain. However, a comparison of DOPC with POPC also showed the importance of the position of the acyl chain. I determined a slow reaction kinetic. It could be estimated by a √t dependence of the number density N_surface, which denominates the ROS sticking on the monolayer. The transport of ROS towards the monolayer was found to be diffusive, because it was the slowest process in the reaction. This interpretation was reinforced by a comparison of the temperature dependence of the relative area increase δA/A with the Stokes-Einstein diffusion coefficient of water molecules. The initial ROS concentration c_0 in the trough could be traced back (c_0~ 50 nM), which is indeed a realistic value found in human cells.
Concluding, our results can be understood as a feasibility study. The complexity of the monolayer can be arbitrarily increased, for example by the addition of proteins, allowing the investigation of other oxidative processes occurring in the cell membrane.
The second system allowed the investigation of growth of LC domains during fast compression processes of monolayers. I chose erucic acid monolayers, due to its low line tension and a continuous nucleation phase, enabling the formation of fractal domains. The monolayers were investigated with isotherms and BAM videos. Since v_C (compression speed of the monolayer) was continuous over the whole compression time, I had a system with well-defined hydrodynamic conditions. This allowed me a complete analysis of the system, starting with descriptive features of the observed domains to a classification of the observed growth regimes by means of hydrodynamic theory, through to the distinction and quantification of different kind of flows and supersaturations, involving Ivantsov theory:
Dependent on the compression speed v_C, I observed seaweed or dendritic domains. The LE/LC phase transition pressure pi_t was slightly increased compared to pi_inf of the equilibrium isotherm. A high compression speed v_C induced a supersaturation Δc. I introduced the excess lateral pressure Δpi=pi-pi_inf as an appropriate quantity to describe the supersaturation Δc. I showed a linear behavior of Δc on Δpi. Δc is a macroscopic quantity since it is averaged over the whole monolayer area. I characterized the domains of the seaweed and dendritic regime with respect to tip radii, branch lengths, side branch separations and fractal dimensions. I calculated the growth speed of the main branches. A roughly doubling of the growth speed of dendritic domains, compared to seaweed domains was observed. This was an evidence of adjunctive (Marangoni) flow in the subphase.
For each monolayer, I observed drifts during domain growth, which I explained by an anisotropy in the LE-phase, caused by the continuous nucleation of the domains. These kind of surface flows were superimposed to bulk flows in the subphase. Since I had a well established system, I could analyze the influence of these surface flows on domain shape, in terms of magnitude, direction and duration of the surface flows. I therefore used FFT spectra and directionality histograms. At low flows, the FFT showed six-fold symmetry. Higher drifts exhibited incisions in the FFT, eventually leading to dumbbell shaped FFTs at very high drifts. The domains grew preferentially in the direction parallel to the incision.
I used directionality histograms to analyze the angular distribution of the growing domains. They showed that the drift direction always correlated with a minimum in the histogram. In order to analyze drift duration, I split the domain in downstream and upstream side. I could show that for small drift durations, downstream growth was preferred. However, for longer drift durations, the flows got more isotropic and consequently growth was more balanced then.
I could observe only a weak correlation between drift velocity v_D and compression speed v_C. However, dendrites were formed when the compression speed v_C was high, while seaweed domains were formed when v_C was small. Domain distortion occurred in the same way, independent if seaweed or dendritic domains were considered. I further showed that hydrodynamic flows in the subphase and surface flows are superimposed and scale differently. Consequently, they have different impact on domain shape: hydrodynamic flows act on μm scale and influence the domain morphology (distance between side branches, and tip radius) and the growth speed of the main branches. Surface flows act on the mm to cm scale, cause an anisotropic flow in the LE phase surrounding the domain, and thus affect the overall domain shape.
The anisotropy in the LE-phase led to a locally different degree of supersaturation. To take this into account, I introduced a local normalized supersaturation Δ, based on the Ivantsov solution. Therefore, I calculated Péclet numbers p of measured quantities of the system. I obtained values of 0.88 ≤Δ≤0.90 for the seaweed regime (p<5) and 0.93 ≤Δ≤0.96 for the dendritic regime (p>6). Since the Ivantsov solution can only be applied for purely diffusive processes, I applied a modified Ivantsov solution Δ_mod, which calculates Δ at a distance 𝛿 ahead of the dendrite tip. I was able to determine the progression of the diffusive layer 𝛿, however a quantitative determination failed.
Applying hydrodynamic theory allowed me to classify the two growth regimes with respect to the Boussinesq number Bq. Since for both growth regimes, I achieved values of Bq<1, bulk viscous losses dominated over surface viscous losses. Further, a cross-over length 𝜉 was calculated, from which one can distinguish, whether advective transport dominates over diffusion.
I further connected the two defined supersaturations Δ and Δc via the excess lateral pressure Δpi. From this, I saw differences in the seaweed and dendritic growth regimes: The local normalized supersaturation Δ of seaweed growth seemed to be quite stable for a further increase of the lateral excess pressure Δpi, whereas it reacted quite sensitive in the dendritic regime. This was found to be an indication of a non-equilibrium regime, caused by the strong coupling of the monolayer to the subphase. It reinforces therefore the theory of Marangoni-flow.
The findings of this thesis emphasize the importance of understanding highly dynamic compression/expansion processes arising in surfactant monolayers. Using the example of the compression of the alveolus surface, it can be seen that a more realistic model of the pulmonary alveolus is not only enabled by increasing the complexity of the surfactant monolayer (e.g. by adding specific proteins or lipid mixtures to the monolayer). Equally important is the understanding in transport processes and the consequences for the monolayer structure. By the analysis of domain shapes, I presented a method, which is suitable for such a study.
Pyrrolobenzodiazepines (PBDs) are a group of antitumor antibiotics that exert their biological activity by alkylation of guanine bases within the minor groove of double-stranded DNA through nucleophilic attack of the guanine amino group on the PBD imine functionality. In trying to increase both the binding strength and sequence selectivity for further enhancing their biological activity, PBDs were linked to additional DNA binding moieties. Preliminary DNA melting experiments partly also performed in our lab with a series of closely related PBD-naphthalimide and benzimidazole conjugates revealed extraordinary DNA-binding capability of hybrids PBD-NIM and PBD-BIMZ. These studies also indicated the favorable contribution of the piperazine structure on drug binding to the DNA duplex. Previously, in vitro cytotoxicity studies also showed promising antitumor activity of both compounds with PBD-BIMZ having the largest cytotoxic potential among various examined conjugates. In the present work, the kinetics, thermodynamics and structural details of the drug-DNA interactions have been determined employing a variety of spectroscopic, calorimetric and computational methods. Thus, a high thermal duplex stabilization upon DNA binding could be ascertained for both drugs and attributed to their covalent attachment to the DNA guanine bases. The 1:1 binding stoichiometry as well as the exclusive minor groove binding for the benzimidazole and the mixed minor grove - intercalative type of binding for the naphthalimide hybrid could be verified by several spectroscopic methods including NMR spectroscopy. Furthermore, by using a combination of solution NMR and some of the most recent molecular modeling techniques, the first high-resolution structures of DNA-drug complexes with PBD hybrid drugs could be obtained giving detailed insight into the specific drug-DNA interactions. Thus, details on van der Waals and hydrogen bond contacts within the complex and the tight fit of the benzimidazole hybrid into the DNA minor groove could be revealed. By using recent data analysis techniques like clustering algorithms, the high flexibility of the piperazine moiety within the PBD-BIMZ-DNA complex could be nicely captured and visualized. Additionally, a thermodynamic analysis for the non-covalent drug binding by UV and fluorescence spectroscopy as well as by direct calorimetric methods revealed a 1:1 binding mode driven by enthalpy changes and counteracted by unfavorable entropic contributions to result in moderately strong association constants. Analysis of the solvent-accessible surface area confirmed the importance of hydrophobic effects on drug binding and the combination of these data with ITC measurements allowed for an extensive thermodynamic characterization of the drug binding process. With respect to the influence of the individual drug moieties on DNA binding, the importance of the piperazine ring for drug-DNA interactions and the basis for its capability to enhance drug binding were addressed. Furthermore, it could be shown that the naphthalimide and benzimidazole moieties also impart additional sequence selectivity to the alkylating PBD structural unit and these distinct differences in the sequence selectivity could be linked to the three-dimensional structures of the DNA-drug complexes. Clearly, the combination of detailed structural and thermodynamic data of complex formation allows for a better understanding of the binding mechanism and structure-activity relationship when it comes to drug-DNA interactions. Therefore, the information gathered can assist in the design of more efficient derivatives of this type of alkylating DNA binding drugs in particular and of DNA recognition by ligands composed of several motifs in general.
Therapeutic Sealing of Proximal Tooth Surfaces: Two-Year Clinical and Radiographic Evaluation
(2009)
The diagnosis, prevention and treatment of proximal carious lesions comprise a constant problem in clinical dentistry. The purpose of this investigation was to test the safety and clinical effect of a new treatment for proximal caries. In 50 patients with two proximal initial lesions (D1-3 without cavitation, bitewing X-ray), orthodontic rubber rings were applied to gain access to the interproximal space. One of the lesions was sealed with a thin polyurethane-dimethacrylate foil using a bonding agent (Heliobond®, Vivadent, Schaan/Liechtenstein); the other lesion received oral home-care with dental floss and fluoridated toothpaste and was left as control. In clinical follow-ups after 6 and 12 months and X-ray evaluation after two years, clinical retention of proximal tape and the underlying sealant, marginal adaptation, discoloration, tooth vitality, proximal plaque and gingivitis were checked. In addition, caries was assessed clinically and radiographically. The sealants showed good retention, marginal adaptation and colour. After two years, vitality of all teeth was still positive and no relevant differences in plaque accumulation or gingival status were found between sealed and control teeth. Two sealed surface had to be filled due to caries progression (D3 with cavitation). 9 sealed lesions showed caries regression. In contrast, only 4 control lesions regressed and also two showed progression. The loss of tape had no significant influence on the lesion progression indicating the effect of the underlying bond. All other sealants and control lesions were stable indicating an arrest of the lesion. In conclusion, sealing initial proximal lesions showed no clinical problems and mostly arrest of initial carious lesions on bitewing X-rays.
In the present work, a time- and radial-dependent fluid model has been developed to describe the glow-to-arc transition of the positive column in the course of constriction. The self-consistent model comprises the particle balance equations for the relevant species, the balance equation of the mean electron energy and the heavy particle temperature in the plasma, the Poisson equation for the space-charge potential, and a current balance determining the axial electric field. The model adopts the nonlocal moment method, i.e., the system of the balance equations resulting from the moments of the radially dependent Boltzmann equation is solved. The electron transport and rate coefficients are adapted as functions of the mean energy of the electrons, the gas temperature and the ionization degree. The model is applied to a description of the constriction of the dc positive column in argon, for a wide range of pressures and applied currents. Pronounced nonlocal features of the mean electron energy balance are found and their influence on the constricted argon positive column is analyzed. Different assumptions concerning the electron velocity distribution function (EVDF) have been considered in the present model. The assumption of a Maxwellian distribution for the electrons was found to be inappropriate, while the assumption of a Druyvesteyn distribution for the electrons was found to be suitable for describing qualitatively the glow-to-arc transition. However, the standard model using the EVDF obtained from the solution of the steady-state, spatially homogeneous electron Boltzmann equation including electron-electron collisions allows to describe the constriction effect and provides best agreement with experimental data and other available modelling results. The fluid model has also been used to study a medium-pressure pulsed positive column in xenon at conditions of the contracted discharge. The simulation results provide a detailed insight in the physical mechanisms of xenon discharges in pulsed mode. The stepwise ionization of the excited atoms, the conversion of the atomic ions into molecular ions as well as the dissociative recombination of the molecular ions are found to be the most important processes for the pulsed positive column in xenon plasmas at conditions of the contracted discharge. The comparison of the model predictions with experimental results generally shows good agreement. In particular, the model predictions are suitable for qualitative reproduction of the significant increase of low-lying atomic levels densities as well as of the higher and of the relaxed lowest vibrational states of the Xe2* excimers in the afterglow phase of the pulse.
An already existing shortage of nurses was exacerbated by the COVID-19 pandemic. Inactive (former) nurses were regarded as a so-called silent reserve and were called upon by various agencies to volunteer for nursing. The question arose as to what factors might encourage or hinder such volunteering and facilitate deployment.
First, inactive nurses were asked via an online survey whether they had registered for deployment or not and what the reasons were for this decision. Further information on professional background was collected, including the reason for having left the profession in the first place. Based on the results of the online survey, focus group discussions were conducted with registered and unregistered inactive nurses, with nurses who had returned to the profession permanently, and with care home managers.
Only one third of the participants in the online survey said they had registered for a temporary assignment during the pandemic. The main reasons for registering were that inactive nurses ‘wanted to do their bit’ to manage the crisis, felt it was their duty and/or felt a sense of belonging to the nursing profession. The main reasons given for not having registered was that respondents ‘could not see a reason at the moment’, had health concerns, and ‘other relevant job commitments’. The majority of respondents still had jobs related to health, care or nursing.
The topics covered in the focus group discussions included the following: perception of the pandemic as a crisis, identity as a nurse and sense of professional commitment, role of current occupation in the decision to register, winning over inactive nurses with a very negative attitude towards returning to care during a crisis situation, support measures and offers regarding a deployment in nursing.
Both in the online survey and in the focus group discussions, a sense of belonging to the nursing profession was evident among many participants. However, this identity does not necessarily lead to a willingness to return to nursing during a crisis situation. Weighing up the risk of deployment against the positive or negative experiences gained during the active period can influence willingness. However, the possibility of taking a break from current work and returning to nursing at short notice is not always given. Many inactive nurses continue to work in the health sector and fulfil equally important tasks during a crisis situation which render them unavailable for deployment.
Different kinds of support for those willing to return to nursing during a crisis situation and communication on conditions of deployments need to be implemented and continuously improved to offer the inactive nurses the greatest possible security and to enable a largely unbureaucratic deployment.
Background: Microvascular Decompression represents an effective treatment for hemifacial spasm. The use of lateral spread responses (LSRs) monitoring remains a useful intraoperative tool to ensure adequate decompression of the facial nerve. Objective: To assess the value of LSRs intraoperative monitoring as a prognostic indicator for the outcome of microvascular decompression in hemifacial spasm. Methods: Our study included 100 patients prospectively. The patients were classified into 4 groups whether LSRs were totally, partially, not relieved or not detected from the start. According to clinical outcome, the patients were classified into 4 groups depending on the clinical course after surgery and the residual symptoms if any. Then, correlations were made between LSRs events and treatment outcome to detect its reliability as a prognostic indicator. Results: LSRs were relieved totally in 56% of the patients, partially relieved in 14%, not relieved in 10% and were not detected in 20% of the patients from the start. HFS was relieved directly after operation in 62% with clinical improvement of 90-100%. 31% described 50-90% improvement over the next 3 months after surgery. Almost all of these 31% (28 out of 31 patients) reported further clinical improvement of 90-100% within one year after surgery. 3% suffered from a relapse after a HFS-free period and 4% reported minimal or no improvement describing 0-50% of the preoperative state. The percentage of the satisfied patients with the clinical outcome who reported after one year a clinical improvement of 90-100% was 90%. Statistical analysis did not find a significant correlation between the relief of LSRs and clinical outcome. Conclusion: LSRs may only represent an intraoperative tool to guide for an adequate decompression but failed to represent a reliable prognostic indicator for treatment outcome.
The UNESCO Man and the Biosphere Programme has been active in South Africa for almost 20 years. The country currently has six designated biosphere reserves with a few sites in various stages of the nomination process. Within the South African context, agencies are using a series of seemingly different instruments to practice landscape-scale management. The UNESCO biosphere reserve concept sometimes finds it difficult to obtain prominence amongst these different landscape initiatives. Biosphere reserves are special sites wherein sustainable development is promoted. For this reason, the biosphere reserve concept has much to offer towards long-term sustainable socialecological land management. In our modern age of population growth, dwindling natural resources and a general disconnectedness of humans from nature due to large scale urbanization, there is an urgent need for innovative ways in which to showcase sustainable living practices. South Africa has limited natural, economic and social resources and therefore needs to prioritize where these resources could best be allocated. This dissertation comprises the history of the MAB Programme in South Africa, as well as a multicase study on five existing biosphere reserves. Results from this study indicated that not all biosphere reserves are equally effective in their implementation of the three functions of biosphere reserves and that all biosphere reserves in South Africa face an uncertain future due to pressing challenges. Collective results of the multicase study as well as literature reviews were used to inform options for the future effective implementation of the MAB Programme in South Africa. Options that could contribute towards effective biosphere reserves include more sustainable funding support, and community-based demonstration projects. In addition a new suite of criteria to inform the selection of future biosphere reserves was developed. Biosphere reserves need to be optimally located in order to secure long-term efficiency and effectiveness. These sites need to be representative of biodiversity, efficiently managed and persistent in the long run. Presently in South Africa, new sites for biosphere reserves are nominated in an ad hoc manner. Should their locations be selected discerningly, they offer many benefits to the South African social and environmental landscape that should be recognized and utilized. The final suite of selection criteria are structured according to four subsections, namely a general section that addresses national matters of general concern to the MAB Programme, and three sections covering the three biosphere reserve functions of conservation, sustainable development and logistic support. This suite of biosphere reserve selection criteria for South Africa is being put forward for deliberation and discussion at local, provincial and national level. It has the potential to be of valuable assistance in selection processes for future effective and efficient biosphere reserves that will proudly earn their place in the South African landscape as “special places for people and nature”.
The southern Baltic Sea embodies an incomparable geological archive of the tectonic evolution of the 450 Ma old Trans‐European Suture Zone (TESZ). This WNW to NW trending suture formed during the collision of Baltica and Avalonia and has accommodated the repeatedly changing stress regimes since then, as evidenced by numerous fault zones and systems. The German offshore part in the vicinity of Rügen Island is strongly block‐faulted, with each block showing a specific geological pattern, enabling the reconstruction of the structural evolution of the area.
The work of this thesis is part of the USO working group of the University of Greifswald and the Geological Survey of Mecklenburg‐Western Pomerania, which aims to build a unified three‐dimensional tectonic model of the southern Baltic Sea area. This thesis presents the results of new structural investigations of the Arkona, Wolin and Gryfice blocks north and east of Rügen. Especially, conflicting structural analyses in the previous work are united into a consistent model.
The integrated interpretation of 144 reprocessed seismic vintage lines (original Petrobaltic data) and 23 high resolution academic seismic sections (from the Universities of Hamburg and Bremen), with additional consideration of on‐ and offshore wells, revealed 19 seismostratigraphic horizons that subdivide the succession between the Proterozoic basement and the Upper Cretaceous. Up to 100 faults of superior fault zones and systems control the tectonic situation. Besides NW trending deep faults formed during the Palaeozoic, for instance the Wiek and Nord Jasmund faults, and NNW trending Mesozoic faults and flexures that belong to the Western Pomeranian Fault System, other major faults such as the Adler‐Kamień Fault Zone document the polyphase evolution of this area.
The restoration of selected seismic sections support the evaluation of separately generated faults and their reactivation, leading to a subdivision of the tectonic evolution of the area into six stages:
(1) The Caledonian Orogeny (Ordovician/Silurian) was accompanied by a NE‐SW compression, resulting in the formation of the TESZ and an accretionary wedge within the upper crust. (2) The following S to SW trending extension of the Variscan Foreland (Devonian/Carboniferous) triggered the
evolution of the Middle Devonian Old Red Rügen Basin south of the Wiek Fault. Further WNW to NW trending faults (e.g. Nord Jasmund Fault) subdivided the basin. (3) The advancing Variscan Orogeny (Late Carboniferous) caused an increasing NE‐SW orientated compression and subsequently reactivated faults and tilted blocks (e.g. Lohme Sub‐block). (4) The North German Basin and Mid Polish Trough formed by thermic subsidence in the S to SE of the research area during the Permo‐Carboniferous. Simultaneously, the evolution of the Gryfice Graben as part of the Teisseyre‐Tornquist Zone commenced. (5) Due to the Arctic‐North Atlantic Rifting an E‐W trending extension increased. Consequently, grabens such as the Gryfice Graben continued their subsidence. As the stress system rotated counter‐clockwise, the shear strength increased along the NE trending faults. The Western Pomeranian Fault System developed due to intense transtension during the Keuper and Jurassic, and is characterised by pull‐apart structures. (6) In the Upper Cretaceous, a NE‐SW compression, forced by the Africa‐Iberia‐Europe convergence, triggered the reactivation of faults and flexures as reverse ones, the inversion of grabens (e.g. Gryfice Graben), and the formation of anticlines, for instance at the Wolin Block.
This thesis combines the calculation of gridded time structure maps and a detailed fault pattern analysis, and represents the base for a velocity‐ and subsequently depth‐based 3D modelling.
The target specificity of thioredoxin family proteins is determined by electrostatic compatibility
(2021)
The thioredoxin (Trx) family of proteins comprises many key enzymes in redox signaling, that catalyzes specific reversible redox reactions, e.g. dithiol-disulfide exchange reactions, (de-)glutathionylation, trans-nitrosylation, or peroxide reduction. With the analysis of a large number of proteins, as well as a certain redox couple in [article 1] and [article 4], we demonstrated that electrostatic complementarity is the major distinguishing feature that controls the specific interactions of Trxs with their target proteins. The primary aim of this work was to determine the importance of this specific interaction and the prediction, modulation, and engineering of functional redox interactions of Trx family proteins. To understand the role of electrostatic complementarity for the mammalian Trx1-TrxR complex, we generated more than 20 hTrx1 mutants and systematically engineered the electrostatic potential within and outside the contact area with TrxR [article 1]. The effects of these specific alterations distributed all over the protein surface were analyzed by enzyme kinetics, differential scanning fluorimetry (DSF), circular dichroism (CD) spectroscopy, and MD simulations. Trx family proteins have a broad and very distinct substrate specificity, which is a prerequisite for redox switching. In [article 4], we comprehensively compared the classification of various redoxins from all kingdoms of life based on their similarity in amino acid sequence, tertiary structure, and electrostatic properties. These similarities were then correlated to the existence of common interaction partners. Our analyses confirmed that the primary and tertiary structure similarities do not correlate to the target specificity of the proteins as thiol-disulfide oxidoreductases. However, we demonstrated that the electrostatic properties of the protein from both Trx or Grx subfamilies is the major determinant for their target specificity.
Although structurally very similar, CxxC/S-type or class I Grxs act as oxidoreductases and CGFS-type or class II Grxs act as FeS cluster transferases. In [article 3], we re-investigated the structural differences between the two main classes of Grxs to solve the mystery of the missing FeS transferase activity of the CxxC/S-type and the lack of oxidoreductase activity of the CGFS-type Grxs. The presence of a distinct loop structure adjacent to the active site is the major determinant of the Grx function. We confirmed that the function of Grxs can be switched from oxidoreductase to FeS cluster transferase by construction of a CxxC/S-type Grx with a CGFS-type Grx loop and vice versa. Results of several in vitro and in vivo assays together with the detailed structural analyses indicate that not a radically different substrate specificity accounts for the lack of activity, but rather slightly different modes of GSH binding, which is an essential nucleophile required in redox and iron homeostasis.
Various processes within the cell depend on GSH, including redox reactions, reversible posttranslational modifications, and iron metabolim. GSH is not only important in the export of FeS precursors from mitochondria, but it is also an essential cofactor for cluster binding in iron sulfur Grxs. In [article 2], we discussed the role of GSH and iron sulfur Grxs in iron metabolism, the physiological role of CGFS-type Grx interactions with BolA- like proteins, and the cluster transfer between Grxs and recipient proteins. The first well characterized physiological function of a Grx-BolA hetero complex is presented with the Grx3/4-Fra2-mediated regulation of iron homeostasis in yeast.
In synopsis, the results presented and discussed in these articles and the manuscript support the concept of electrostatic properties as the main determinant in substrate specificity towards functional predictions in Trx family proteins. The mathematical model presented here showed significantly accuracy and precision in function prediction. We are aware that our findings are focused on Trx family proteins as a particular family of proteins, but by using a machine learning strategy this mathematical model is being trained with numerous different protein models for better efficacy and accuracy, that may lead to new insights also in the specific interactions of other protein families. The new concept for the substrate specificity determinant doesn’t eliminate previously described aspects for molecular recognition, instead it reveals a deeper understanding of the protein-protein interaction. The 3D structural elements of a protein play a significant role in the specificity and function. We have been able to activate an inactive protein by replacing defined structural elements. Elimination of the loop structure from CGFS-type Grx5 transformed it from an FeS transferase into an oxidoreductase and the activity was further increased by modification of the active site. We believe that the present findings may be useful to investigate proteins in great detail regarding their function based on structure and electrostatic properties. Understanding the nature of the specific interactions may enable us to specifically modify the signal transduction pathways.
Given a manifold with a string structure, we construct a spinor bundle on its loop space. Our construction is in analogy with the usual construction of a spinor bundle on a spin manifold, but necessarily makes use of tools from infinite dimensional geometry. We equip this spinor bundle on loop space with an action of a bundle of Clifford algebras. Given two smooth loops in our string manifold that share a segment, we can construct a third loop by deleting this segment. If this third loop is smooth, then we say that the original pair of loops is a pair of compatible loops. It is well-known that this operation of fusing compatible loops is important if one wants to understand the geometry of a manifold through its loop space. In this work, we explain in detail how the spinor bundle on loop space behaves with respect to fusion of compatible loops. To wit, we construct a family of fusion isomorphisms indexed by pairs of compatible loops in our string manifold. Each of these fusion isomorphisms is an isomorphism from the relative tensor product of the fibres of the spinor bundle over its index pair of compatible loops to the fibre over the loop that is the result of fusing the index pair. The construction of a spinor bundle on loop space equipped with a fusion product as above was proposed by Stolz and Teichner with the goal of studying the Dirac operator on loop space". Our construction combines facets of the theory of bimodules for von Neumann algebras, infinite dimensional manifolds, and Lie groups and their representations. We moreover place our spinor bundle on loop space in the context of bundle gerbes and bundle gerbe modules.
The present work is the first work dealing with turbulence in the WEGA stellarator. The main object of this work is to provide a detailed characterisation of electrostatic turbulence in WEGA and to identify the underlying instability mechanism driving turbulence. The spatio-temporal structure of turbulence is studied using multiple Langmuir probes providing a sufficiently high spatial and temporal resolution. Turbulence in WEGA is dominated by drift wave dynamics. Evidence for this finding is given by several individual indicators which are typical features of drift waves. The phase shift between density and potential fluctuations is close to zero, fluctuations are mainly driven by the density gradient, and the phase velocity of turbulent structures points in the direction of the electron diamagnetic drift. The structure of turbulence is studied mainly in the plasma edge region inside the last closed flux surface. WEGA can be operated in two regimes differing in the magnetic field strength by almost one order of magnitude (57mT and 500mT, respectively). The two regimes turned out to show a strong difference in the turbulence dynamics. At 57mT large structures with a poloidal extent comparable to the machine dimensions are observed, whereas at 500mT turbulent structures are much smaller. The poloidal structure size scales nearly linearly with the inverse magnetic field strength. This scaling may be argued to be related to the drift wave dispersion scale. However, the structure size remains unchanged when the ion mass is changed by using different discharge gases. Inside the last closed flux surface the poloidal ExB drift in WEGA is negligible. The observed phase velocity is in good agreement with the electron diamagnetic drift velocity. The energy in the wavenumber-frequency spectrum is distributed in the vicinity of the drift wave dispersion relation. The three-dimensional structure is studied in detail using probes which are toroidally separated but aligned along connecting magnetic field lines. As expected for drift waves a small but finite parallel wavenumber is found. The ratio between the average parallel and perpendicular wavenumber is in the order of 10^-2. The parallel phase velocity of turbulent structures is in-between the ion sound velocity and the Alfvènvelocity. In the parallel dynamics a fundamental difference between the two operational regimes at different magnetic field strength is found. At 500mT turbulent structures can be described as an interaction of wave contributions with parallel wavefronts. At 57mT the energy in the parallel wavenumber spectrum is distributed among wavenumber components pointing both parallel and antiparallel to the magnetic field vector. In both cases turbulent structures arise preferable on the low field side of the torus. Some results on a novel field in plasma turbulence are given, i.e. the study of turbulence as a function of resonant magnetic field perturbations leading to the formation of magnetic islands. Magnetic islands in WEGA can be manipulated by external perturbation coils. A significant influence of field perturbations on the turbulence dynamics is found. A distinct local increase of the fluctuation amplitude and the associated turbulent particle flux is found in the region of magnetic islands.
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.
As the tree of life is populated with sequenced genomes ever more densely, the new challenge is the accurate and consistent annotation of entire clades of genomes. In my dissertation, I address this problem with a new approach to comparative gene finding that takes a multiple genome alignment of closely related species and simultaneously predicts the location and structure of protein-coding genes in all input genomes, thereby exploiting negative selection and sequence conservation. The model prefers potential gene structures in the different genomes that are in agreement with each other, or—if not—where the exon gains and losses are plausible given the species tree. The multi-species gene finding problem is formulated as a binary labeling problem on a graph. The resulting optimization problem is NP hard, but can be efficiently approximated using a subgradient-based dual decomposition approach.
I tested the novel approach on whole-genome alignments of 12 vertebrate and 12 Drosophila species. The accuracy was evaluated for human, mouse and Drosophila melanogaster and compared to competing methods. Results suggest that the new method is well-suited for annotation of a large number of genomes of closely related species within a clade, in particular, when RNA-Seq data are available for many of the genomes. The transfer of existing annotations from one genome to another via the genome alignment is more accurate than previous approaches that are based on protein-spliced alignments, when the genomes are at close to medium distances. The method is implemented in C++ as part of the gene finder AUGUSTUS.
The role of uptake and efflux transporters in the pharmacokinetics of ß1-receptor blocker talinolol
(2016)
Introduction: The β1-adrenergic receptor antagonist talinolol is a probe drug for P-glycoprotein (P-gp). It is absorbed erratically and incompletely from the gastrointestinal tract. However, its pharmacokinetics might also be influenced by further uptake and efflux transporters as concluded from interaction studies with naringin and verapamil in human. Additionally, the transcellular transport through the different tissues, including enterocytes, hepatocytes and kidney tubular cells, is not completely understood so far. Therefore, we aimed to measure the affinity of talinolol to drug transporting proteins (OCT1-3, PEPT1, OCTN2, ASBT, NTCP, MRP 1-3 and P-gp as well as OATP 1B1, 1B3, 2B1 and 1A2) and some of their genetic variants known to be of pharmacokinetic relevance (OATP1A2 *2 and*3 as well as OATP2B1 V201M, R312Q and S486F). In a further step, we retrospectively evaluated the impact of clinically relevant genetic polymorphisms of transporters on the pharmacokinetics of talinolol in healthy subjects. Materials and Methods: Time and concentration-dependent uptake assays with [3H]-talinolol were performed either in stable transfected HEK293 or MDCKII cells expressing OATP1A2 *1, *2 and *3, OATP1B1, OATP1B3, OATP2B1 (and its genetic variants p.V201M, p.R312Q and p.S486F), NTCP, ASBT, PEPT1, OCTN2, OCT 1-3 and the respective vector control or in inside-out lipovesicles expressing the efflux transporters MRP1-3 and P-gp. Talinolol was quantified by liquid scintillation counting. The transport rates were then corrected by the transporter proteomics measured in the cellular membrane. Regarding the pharmacogenomic evaluation, it was carried out retrospectively in 39 healthy subjects who had participated in former pharmacokinetic studies with talinolol. This evaluation included a variety of transporter related genetic variants, known to be of a clinical meaning for their substrates. Results: Among the uptake transporters, talinolol was shown to be a substrate of OATP1B3 (Km= 153 ± 137 μmol/l; Vmax= 168 ± 30.3 μmol/mgxmin), OATP1B1 (Km= 301 ± 133 μmol/l; Vmax= 1135 ± 348 μmol/mgxmin), OATP2B1 (Km= 459 ± 260 μmol/l; Vmax= 4.32 ± 1.33 μmol/mgxmin), OATP1A2 (Km= 477 ± 158 μmol/l; Vmax= 0.61 ± 0.1 μmol/mgxmin) and NTCP (Km= 2560 ± 781 μmol/l; Vmax= 15944 ± 3741 μmol/mgxmin) but not a substrate of OCT1-3, OCTN2, PEPT1 or ASBT. When it comes to the efflux transporters, talinolol was transported by both P-gp (Km = 175 ± 206 mol/l; Vmax = 14 ± 10.8 nmol/mgxmin) and MRP3 (Km= 86.8 ± 62.8 μmol/l; Vmax= 133 ± 51.5 μmol/mgxmin) but not by MRP2. The pharmacogenomic analysis supported the in-vitro results, as it showed a significant decrease in talinolol absorption (AUC and Cmax) in subjects with the loss of function variant MRP3 211C>T and in those with a decreased P-gp function due to having less than 5 T-allels in the haplotype P-gp 1236-2677-3435-TTT. No significant changes were found associated with other transporters’ genetic variants. Conclusion: Our in-vitro results suggested the vectorial transport of talinolol through the enterocytes to consist mainly of apical OATP2B1 and P-gp and basolateral MRP3. Additionally in the hepatocytes, apical OATP1B1, OATP1B3 and NTCP seem to be involved as well. This vectorial transport was demonstrated in-vivo for the first time by our pharmacogenomic analysis, where talinolol absorption was significantly influenced by both P-gp and MRP3 genetic variants.
The proteasome is a major part of the ubiquitin-proteasome-system playing an important role in cell homeostasis due to its protein quality control function. Moreover, the proteasome is involved in cell cycle regulation and in the regulation of transcription factors. Upon induction of interferons, or treatment with lipopolysaccharides, an isoform of the standard-proteasome is composed, named immunoproteasome (i-proteasome). The i-proteasome is constitutively expressed in immune cells and deficiency of proteolytic subunits of this multiprotein complex has been associated with a poor outcome during infectious diseases. I-proteasome-deficiency has been shown to result in reduced MHC class I presentation. Using mice which are deficient for all three proteolytic active subunits LMP2, MECL-1 and LMP7, we could demonstrate that i-proteasome-deficiency lead to an altered recruitment of immune cells to the CNS when challenged with the intracellular parasite Toxoplasma gondii, resulting in increased frequencies of neutrophils and other cells of myeloid origin. The shift to reduced frequencies of CD45highCD11blow lymphocytes can be further explained by a decreased migratory capacity of i-proteasome-deficient CD8+ T cells. In contrast to previous studies using other pathogens, effector function of CD8+ as well as CD4+ T cells, measured by frequencies of IFNγ, TNF, IL-2 and granzyme B producing cells, were not impaired in these mice, whereas induction of CD4+ Tregs was strongly reduced. In addition, we found that parasite control was comparable to control mice and that i-proteasome deletion caused an overall pro-inflammatory cytokine milieu within the brain. Our results indicate that i-proteasome-deficiency lead to prolonged tissue inflammation during T. gondii infection which could be an explanation for the more severe course of disease observed in these mice.
The Src homology domain containing phosphatase 2 (SHP2) is a tyrosine phosphatase modulating several signaling pathways and therefore has an influence in cell cycle, differentiation, proliferation and cell activation. However, SHP2 is assumed to play a negative role during T-cell activation as the phosphatase has been shown to inhibit T-cell receptor-induced signaling cascades. Although, various gain-of-function mutations in the SH2 or PTP domain of this phosphatase, such as D61Y, have been associated with myeloproliferative diseases such as juvenile myelomonocytic leukemia (JMML), effects of such mutations on T cells have not been addressed in scientific literature so far. Therefore, in the second part of this thesis we could demonstrate that D61Y mutation in the SH2 domain of SHP2 did not cause JMML pathology when only introduced into T cells. Especially in aged mice, T cells of SHP2 mutant mice showed an increased expression of cell adhesion molecule CD44. In accordance with these findings, we observed increased influenza A virus-specific T cells in the bone marrow of SHP2 D61Y mutant mice, indicating a role of the phosphatase in memory formation or maintenance of CD8+ Tem. Although SHP2D61Y mice revealed a comparable viral clearance, IFNγ production of virus experienced CD4+ and CD8+ T cells was diminished compared to control mice, underlining a negative involvement of the phosphatase in the JAK/STAT1 signaling axis as suggested before by studies using mice with SHP2-/- T cells.
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.