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Institute
- Institut für Physik (7)
- Zoologisches Institut und Museum (6)
- Institut für Biochemie (5)
- Institut für Botanik und Landschaftsökologie & Botanischer Garten (5)
- Institut für Mikrobiologie - Abteilung für Genetik & Biochemie (4)
- Abteilung für Mikrobiologie und Molekularbiologie (3)
- Institut für Mathematik und Informatik (2)
- Institut für Politik- und Kommunikationswissenschaft (2)
- Interfakultäres Institut für Genetik und Funktionelle Genomforschung (MNF) (2)
- Poliklinik für Kieferorthopädie, Präventive Zahnmedizin und Kinderzahnheilkunde (2)
The glioblastoma multiforme (GBM) not only presents the most common tumor of the central nervous system in adults, it is also the most aggressive brain tumor. Although patients suffering from GBM standardly receive a combination of multiple treatments including surgery, radiotherapy and chemotherapy, its prognosis is still poor with a median survival time of only 12-15 months. Therefore, new and effective treatment methods are urgently needed.
A signaling molecule which is both involved in proliferation, migration and invasion of a broad range of healthy and malignant cells is the lipid mediator sphingosine-1-phosphate (S1P). Previous studies have confirmed that sphingosine-1-phosphate (S1P) receptor 1 (S1PR1) is involved in the regulation of proliferation, invasion, metastasis, vascular maturation and angiogenesis of GBM cells, and is closely related to the occurrence and development of tumors. Thus, ACT-209905 (provided by Actelion Pharmaceuticals) as a selective S1PR1 modulator was applied to gain insights into the molecular processes activated by S1PR1 in GBM cells using two human (LN18, U87MG) and one murine (GL261) GBM cell line.
In our in vitro cell viability analyses, we found that ACT-209905 significantly reduced viability of LN18 cells in a concentration dependent manner. A combined administration of ACT-209905 with S1PR2 inhibitors (Compound 16, Compound 16ME – both provided by ONO Pharmaceuticals, and JTE-013 – commercially available) showed a stronger effect than the single administration demonstrating that both S1PR1 and S1PR2 are involved in growth of GBM cells and may interact with each other. Our results also demonstrated that ACT-209905 can induce apoptosis in GBM cells since caspase 3 activity was induced by the S1PR1 modulator which might therefore play an important role in inhibiting the proliferation of GBM cells. Further, we found a significant inhibitory effect of ACT-209905 on the migration and invasion of LN18 and U87MG GBM cells arguing for a participation of S1PR1 signaling in migration and invasion of GBM cells, too. Stimulation of S1P receptors results in the activation of several kinases such as AKT1 and ERK1/2, correspondingly our immunoblot analyses showed a strong activation of both kinases by S1P which was reduced by ACT-209905 in LN18 cells but not in GL261 cells suggesting that different pathways are activated by S1P in these GBM cell lines. Further studies have to be performed to clarify the role of AKT1 and ERK1/2 in the inhibitory effects of ACT-209905 on GBM proliferation, migration and invasion.
Currently, GBM stem cells are discussed as a reason for resistance against the radiochemotherapy and the recurrence of the tumor. Our immunoblot analyses showed that Nestin and CD133, two marker proteins for GBM stem cells, were higher expressed in GBM cells treated with ACT-209905 compared to control or S1P treated LN18 cells. Further investigations in the future might contribute to the elucidation of an involvement of the S1P receptors in the stem cell behavior of GBM cells. Paradoxically to the up-regulation of CD133 and Nestin by ACT-209905, treatment of LN18 stem-like neurospheres with ACT-209905 showed a significant cytotoxic effect of the compound which was even more pronounced in the stem-like neurosphere cells compared to the adherent parental LN18 cells.
Overall, the studies of this work improve our understanding of the complex mechanisms of S1P signaling in GBM cells and might drive the development of its pharmacological modulation as a new therapeutic principle in GBM. Furthermore, an extended knowledge about the molecular effects of ACT-209905 on GBM cells will broaden the understanding for possible future applications and clinical indications.
The synthesis of pterin-dithiolene ligands was achieved by employing the radical nucleophilic substitution, i.e. the so-called “Minisci- Reaction”1. This protocol was used for the first time by Professor W. Pfleiderer on pterin substrates2 and proved a powerful method for the preparation of 6 acyl-pterins in course of this work. Subsequent construction of the dithiolene ring facilitates the synthesis of pterin-dithiolene ligands with completely unprotected pterin moieti.
The molybdenum cofactor is probably one of the most relevant discoveries in the recent history of pterin chemistry and biochemistry. Many efforts have been made for the preparation of compounds able to mimic the features of the Moco ligand system called "Molybdopterin". In fact, the study of MPT models enables a deeper understanding of the “mechanism of function” of this cofactor and most importantly, lays the foundation for a potential treatment for the Moco related diseases MoCOD and iSOD.
Class I and class II glutaredoxins (Grxs) are glutathione (GSH)-dependent proteins, that function as oxidoreductases (class I) or mediate cellular iron trafficking (class II). Some members of class I Grxs like human Grx2 are able to complex a [2Fe-2S] cluster and form a dimeric holo complex, which renders them catalytically inactive and is the basis for their function as redox sensors. Class II Grxs like human Grx5 also complex [2Fe-2S] clusters, however these proteins transfer the clusters to other proteins. Both functionally distinct classes share a similar thioredoxin fold and conserved interaction sites for the non-covalently binding of GSH, which is required to complex the [2Fe-2S] cluster. Furthermore, the proteins from both classes contain a highly nucleophilic active site cysteine that would allow both classes to catalyze GSH-dependent oxidoreduction reactions. Despite of these similar features, only class I Grxs are able to form a mixed disulfide with GSH and to reversibly transfer it to protein thiols (de-/glutathionylation). Interestingly, neither class I Grxs nor class II Grxs can effectively compensate the loss of an essential member of the other class. Even though some structural differences were described earlier, the basis for their different functions remained unknown. In particular, the lack of catalytic activity of class II Grxs as oxidoreductases could not be explained. Here, we demonstrate that the different conformations of a conserved lysyl side chain are the molecular determinant of the oxidoreductase or Fe-S transfer activity of class I and II Grxs, respectively. A specific loop structure that is conserved in all class II Grxs determines one lysyl conformation that prevents the formation of a mixed disulfide of the active site cysteinyl thiol with GSH. Using engineered mutants of hGrx2 and hGrx5, we demonstrated that the exchange of the distinct loop between the classes results in a loss of oxidoreductase function of class I hGrx2 and the gain of oxidoreductase activity of class II hGrx5. The altered GSH binding mode also profoundly changes the [2Fe-2S] cluster binding of the engineered mutants and thereby also influences stability of the holo complexes, a pre-determinant for [Fe-S] cluster transfer activity. With the minor shift of 2 Å in a conserved lysyl side chain orientation we were not only able to modify the catalytic activity of two small human mitochondrial proteins, but on a much larger scale also provided evidence for the previously unknown structural basis that determines the function of all class I and class II Grxs.
The oxidoreductase activity of hGrx2 was also analyzed in vivo in a model of doxorubicin cell toxicity. Applying a mass spectrometrical approach, we identified various mitochondrial proteins as targets for redox regulation. Furthermore, our results gave reason to reconsider some common assumptions regarding doxorubicin-induced apoptosis and the protective function of mitochondrial Grx2.
Abstract
Background: Behavior management techniques (BMT) are essential in order to
achieve a successful dental treatment with a minimum amount of stress in paediatric
dentistry, but parents are not equally accepting different advanced BMT.
Purpose: To investigate the differences in parental acceptance of advanced
behavior management techniques between University of Greifswald/Germany and
Jordan University/Jordan.
Methods: Parents of the children treated in the pedodontic departments at the
University of Greifswald/Germany and Jordan University/Jordan rated their
acceptance level of four advanced behavior management techniques (passive
restraint, active restraint, nitrous oxide sedation and general anesthesia) for normal
treatment, and for urgent treatment using a five points Likert scale. 200 parents (100
in each university) completed the questionnaire forms for analysis.
Results: Nitrous oxide sedation was rated the most accepted technique in
Greifswald and Jordan (mean 3.78±1.34; 3.22±1.50, respectively). The least
acceptable technique in Greifswald was passive restraint (2.05±1.18) and in Jordan
general anesthesia (2.11±1.30). The parents in Greifswald are significantly more
accepting nitrous oxide sedation than parents in Jordan (p=0.010), while parents in
Jordan are significantly more willing to accept passive restraint (p=0.001). The
acceptance of all advanced behavior management techniques increased significantly
in both groups when the treatment is urgent (p≤0.05),
Conclusions: Parental culture and the urgency of the treatment affect the
acceptance to different behavior management techniques. Moreover, the parental
attitude to the pharmacological technique has changed, as nitrous oxide sedation
generally appears to be the most preferred advanced technique in both groups.
African swine fever virus (ASFV) is one of the most threatening animal viruses which has dramatically expanded its distribution range within the last years. ASFV was first described and is endemic in sub-Saharan Africa where it is transmitted in a sylvatic cycle between indigenous suids and Ornithodoros soft ticks. Therefore, ASFV is the only known DNA-arbovirus and, in addition to that, the only member of the genus Asfivirus within the family Asfarviridae. Being highly infectious to domestic pigs and wild boar, the virus was introduced into Georgia in 2007 and has subsequently spread throughout eastern Europe reaching the European Union in 2014. Despite almost 100 years of intensive research and the occurrence of African swine fever (ASF) on four continents including Europe, many aspects of its epidemiology, vector dynamics and virus evolution are unknown. In our study, first evidence is presented on endogenous ASFV-like (EASFL)- elements which are integrated into the genome of ASFV natural vectors, O. moubata soft ticks. Through a series of experiments including next-generation sequencing, infection experiments, phylogenetic and BEAST analyses as well as PCR-screening, evidence is provided that these elements belong to an ancestral ASFV strain that might have existed 50,000 to 30,000 years BCE. Further results suggest that the EASFL-elements are involved in protecting ticks against ASFV infection and might belong to a generalised tick defence mechanism. In order to evaluate factors influencing ASFV epidemiology in eastern Europe, experiments were conducted on possible indigenous vector species and circulating virus isolates. In the absence of the natural tick vector, blow fly larvae were considered as possible mechanical vectors involved in ASFV transmission and persistence. Results are presented that even after feeding on highly infectious wild boar tissue, fly larvae and pupae showed no contamination with infectious virus. On the contrary, the maggots appeared to have inactivated the virus in the organ tissue through their salivary secretions. Further experiments conducted on an ASFV-strain isolated from northeastern Estonia resulted in the first report of an ASFV-strain with attenuated phenotype isolated in Eastern Europe. Results from NGS-analyses provided evidence for a major genome reorganisation in that strain that included a large deletion and a duplication of multiple ASFV genes.
Taken together, this study provides novel insights into the epidemiology of ASF and evolution of ASFV one of the major threats to animal health worldwide and therefore does not only contribute significantly to basic research but possibly also to specific knowledge necessary for future disease management.
Chemosymbiosis in marine bivalves – unravelling host-symbiont interactions and symbiotic adaptions
(2018)
Symbiosis essentially forms the cornerstone of complex life on earth. Spearheading
symbiosis research in the last few decades include the exploration of diverse mutualistic
animal-bacterial associations from marine habitats. Yet, many facets of symbiotic
associations remain under-examined. Here we investigated marine bivalves of the genera
Bathymodiolus and Codakia, inhabiting hydrothermal vents and shallow water
ecosystems, respectively, and their bacterial symbionts. The symbionts reside
intracellularly within gill epithelia and supply their host with chemoautotrophically fixed
carbon. They oxidize reduced substrates like sulfide (thiotrophic symbionts) and methane
(methanotrophic symbionts) from surrounding fluids for energy generation. The nature of
interactions between host and symbiont at the metabolic and physical level, as well as
between the holobiont and its environment remain poorly understood. In vitro cultivations
of both symbiont and host are difficult till date, hampering the feasibility of targeted
molecular investigations.
We bypassed culture-based experiments by proteogenomically investigating physically
separated fractions of host and symbiont cell components for the bivalves Bathymodiolus
azoricus, Bathymodiolus thermophilus and Codakia orbicularis. Using these
enrichments, we sequenced the symbionts’ genomes and established semi-quantitative
host-symbiont (meta-) proteomic profiles. This combined approach enabled us to resolve
symbiosis-relevant metabolic pathways and adaptations, detect molecular factors
mediating physical interactions amongst partners and to understand the association of
symbiotic traits with the environmental factors prevailing within habitats of the respective
bivalve.
Our results revealed intricate metabolic interdependence between the symbiotic partners.
In Bathymodiolus, these metabolic interactions included (1) the concentration of essential
substrates like CO2 and thiosulfate by the host for the thiotrophic symbiont, and (2) the
host’s replenishment of essential TCA cycle intermediates for the thiotroph that lacks
biosynthetic enzymes for these metabolites. In exchange (3), the thiotroph compensates
the host’s putative deficiency in amino acid and cofactor biosynthesis by cycling aminoacids
derived from imported precursors back to the host. In case of Codakia orbicularis,
the symbionts may metabolically supplement their host with N-compounds derived from
fixation of molecular nitrogen, a trait that was hitherto unknown in chemosynthetic
thiotrophic symbionts.
Individual proteogenomic investigations of the bivalves Bathymodiolus azoricus and
Bathymodiolus thermophilus showed that their symbionts are able to exploit a multitude
of energy sources like sulfide, thiosulfate, methane and hydrogen to fuel chemosynthesis.
The bivalves and their thiotrophic symbionts, however, are particularly adapted to
thiosulfate-utilization, as indicated by mitochondrial production and concentration of
thiosulfate by host and dominant expression of thiosulfate oxidation enzymes in the
symbiont. This may be advantageous, because thiosulfate is less toxic to the host than
sulfide. The central metabolic pathways for energy generation, carbon and nitrogen
assimilation and amino acid biosynthesis in thiotrophic symbionts of both Bathymodiolus
host species are highly conserved. Expression levels of these pathways do, however, vary
between symbionts of both species, indicating differential regulation of enzyme synthesis,
possibly to accommodate differences in host morphology and environmental factors.
Systematic comparison of symbiont-containing and symbiont-free sample types within
and between B. azoricus and B. thermophilus revealed the presence of ‘symbiosisspecific’
features allowing direct host-symbiont physical interactions. Host proteins
engaged in symbiosis-specific functions include 1) a large repertoire of host digestive
enzymes predominant in the gill, possibly facilitating symbiont population control and
carbon acquisition via direct enzymatic digestion of symbiont cells and 2) a set of host
pattern-recognition receptors, which may enable the host to selectively recognize
pathogens or even symbionts “ripe” for consumption. Symbiont proteins engaged in
symbiosis-specific interactions included 3) an enormous set of adhesins and toxins,
putatively involved in symbiont colonization, persistence and host-feeding.
Bathymodiolus symbionts also possess repertoires of CRISPR-Cas and restrictionmodification
genes for phage defense that are unusually large for intracellular symbionts.
Genomic and proteomic comparisons of thiotrophic symbionts of distinct Bathymodiolus
host species from different vent sites revealed a conserved core genome but divergent
accessory genomes. The B. thermophilus thiotroph’s accessory genome was notably more
enriched in genes encoding adhesins, toxins and phage defense proteins than that of other
Bathymodiolus symbionts. Phylogenetic analyses suggest that this enrichment possibly
resulted from horizontal gene acquisition followed by multiple internal gene duplication
events. In others symbionts, these gene functions may be substituted by alternate
mechanisms or may not be required at all: The methanotrophic symbionts of B. azoricus,
for example, has the genetic potential to supplement phage defense functions. Thus, the
accessory genomes of Bathymodiolus symbionts are species- or habitat-associated,
possibly facilitating adaptation of the bivalves to their respective micro- and macroenvironments.
In support of this, we show that symbiont biomass in B. thermophilus,
which hosts only one thiotrophic symbiont phylotype, is considerably higher than in B.
azoricus that hosts thiotrophic and methanotrophic symbionts. This suggests that different
symbiont compositions in each species produce distinct microenvironments within the
holobiont.
Our study presents an exhaustive assessment of the genes and proteins involved in this
bivalve-microbe interaction, hinting at intimate host-symbiont interdependencies and
symbiotic crosstalk between partners. The findings open novel prospects for
microbiologists with regard to mechanisms of host-symbiont interplay within highly
specialized niches, origin and distribution of prokaryote-eukaryote interaction factors
across both mutualistic and pathogenic associations.
The rapid anthropogenic climate change that is projected for the 21st century is predicted to have severe impacts on ecosystems and on the provision of ecosystem services. With respect to the longevity of trees, forestry in particular has to adapt now to future climate change. This requires profound multidisciplinary knowledge on the direct and indirect climate sensitivity of forest ecosystems on various spatial scales. Predictions on growth declines due to increasing drought exposition during climate change are widely recognized for European beech (Fagus sylvatica L.), which is the major forest tree in European temperate deciduous forests. However, research from other continents or other biomes has shown that winter climate change may also affect forest growth dynamics due to declining snow cover and increased soil cooling. So far, this winter cold sensitivity is largely unexplored in Europe. Thus, particularly focussing on forest growth dynamics and winter cold sensitivity, the goal of this PhD-project was to explore how climate sensitivity of forest ecosystems differs regionally. By doing so, the project aimed to deliver insights about possibilities and limits of upscaling regional knowledge to a global understanding of climate sensitivity. To achieve these goals, this PhD-project integrated five studies (Manuscripts 1–5) that investigated the climate sensitivity of biogeochemical cycles, plant species composition in forests, and forest growth dynamics across spatial scales. In particular, a large-scale gradient-design field experiment simulated the influence of winter climate change on forest ecosystems by snow cover and soil temperature manipulations (Manuscript 1). This study indicated that soil cooling and decreased root nutrient uptake may indirectly reduce growth of adult forest trees. Moreover, this study indicated uniform ecological sensitivity to soil temperature changes across sites along a large winter temperature gradient (ΔT = 4 K across 500 km), irrespective of the site-specific history of snow cover conditions, which motivates upscaling from local winter climate change studies to the regional scale. Although regional climate drives growth of adult forest trees, local factors, such as site-specific edaphic conditions, might control plants in the forest understory. This assumption was tested by mapping the forest understory composition along the same winter temperature gradient as introduced above (Manuscript 2). Across sites, this study found that edaphic conditions explained the spatial turnover in the forest understory composition more than climate, which might moderate direct climate change impacts on the forest understory composition. However, edaphic conditions, forest structure, and climate are linked by triangular interactions. Thus, climate change might still indirectly affect the forest vegetation dynamics. Moreover, a dendroecological study focussed on the same winter temperature gradient from central to cold-marginal beech populations as above in order to identify gradual changes in summer drought and winter cold sensitivity in tree growth (Manuscript 3). Towards the cold distribution margin, the influence of drought on tree growth gradually decreased, while growth reductions were increasingly related to winter cold due to harsher winter climate. By a large-scale dendroecological network study assessed the relationship of growth dynamics to climate and reproductive effort in beech forests across Europe (Manuscript 4). Indeed, this study found the general pattern across the distribution range of beech that high temperature controlled growth indirectly via resource allocation to reproduction. However, the strong, direct drought signal that could be generally detected from dry-marginal to central populations vanished towards the cold-marginal populations, where the more focussed study of Manuscript 3 identified a stronger relationship of tree growth to winter cold. Further extending the scope of this PhD-thesis to global scales, litter decomposition rates were assessed across biomes (Manuscript 5). This study found a robust relationship between climate and decomposition rates, but it also demonstrated large within-biome variability on a local scale. These local scale differences might depend on habitat conditions that, in turn, could be modulated by climate change, which calls for a better exploration of indirect climate sensitivity. In conclusion, this PhD-thesis highlighted that multidisciplinary research can advance the understanding of ecological interactions in forest ecosystems under changing climate scenarios. In this PhD-project, a winter climate change experiment, where site-representative target trees were selected by means of dendroecology, contributed to a mechanistic understanding of winter cold sensitivity in forest growth dynamics. Dendroecological investigations then put the findings in a broader temporal and spatial context by describing local climate sensitivity of tree growth on different spatial scales. This thesis further shows that global generalizations about the relationship of climate and ecological processes in ecosystem models have to be critically reviewed for the need of local and regional adjustment because these processes might experience considerable regional- or local-scale variation. However, this thesis reports uniform sensitivity of ecological processes to altered winter soil temperature regimes across a large winter temperature gradient. Thus, upscaling from insights of previous winter climate change experiments to regional scales is encouraged.
Currently, plastic materials are an integral part of our lives, but their production mostly bases on fossil fuels or derivatives, which resources are decreasing. Extraction and processing of non-renewable resources have also negative impact on environment. One of the most promising and environmentally friendly approaches is use of microorganism. This PhD dissertation presents the non-conventional yeast Arxula adeninivorans as a host for production of bio-based and biodegradable poly(hydroxyalkanoates) plastics poly(hydroxybutyrate) and co-polymer poly(hydroxybutyrate-co-hydroxyvalerate). Additionally, the constructed yeast strain was able to secrete enantiomerically pure (R)-3-hydroxybutyric acid.
The production of PHAs requires three enzymes: β-ketothiolase, acetoacetyl-CoA reductase and PHA synthase. The strategy followed in this project was divided into two parts. While all three enzymes are responsible for intracellular production of PHA polymer, first two only lead to secretion of (R)-3-HB into culture media, which was used in a first stage of work to establish and optimize polymer production. Both, different bacterial strains and yeast A. adeninivorans were taken into account in screening of the genes encoding aforementioned enzymes. Bacterial genes were chemically synthesized using codon optimization pattern and endogenous genes were obtained using PCR and genomic DNA template from A. adeninivorans LS3 wild-type strain. Each gene was cloned into Xplor2 vector between TEF1 constitutive promoter and PHO5 terminator. Vector containing both thiolase and reductase genes was used for A. adeninivorans transformation.
The best combination of heterologous genes was overexpression of β-ketothiolase gene from Clostridium acetobutylicum and acetoacetyl-CoA reductase gene from Cupriavidus necator which led to secretion of 4.84 g L−1 (R)-3-HB, at a rate of 0.023 g L−1 h−1 over 214 h in shaking flask cultivation. Further optimization by fed-batch culturing with glucose as a carbon source did not improve (R)-3-HB secretion, but the rate of production was doubled to 0.043 g L−1 h−1 [3.78 g L−1 of (R)-3-HB at 89 h].
The product of acetoacetyl-CoA reductase is (R)-3-HB-CoA and further removing of CoA moiety is needed for acid secretion into culture media. A. adeninivorans is able to conduct this process without any additional modification but the conversion rate is unknown. Two thioesterases, cytosolic TesBp encoded by TesB gene from E. coli and mitochondrial ATes1p encoded by ATES1 gene from A. adeninivorans, were analysed to enhance secretion process. Additionally, a cytosolic version of ATES1 gene (ATES1cyt) was tested. All three genes were expressed in A. adeninivorans cells under TEF1 constitutive promoter together with thiolase and reductase genes. Despite detected enzymatic activity the yield of (R)-3-HB synthesis and secretion was not increased. Moreover, overexpressed thioesterases negatively influenced cell growth, indicating that they act on other metabolic components. The results provided two sets of information, first, the endogenous secretion system is sufficient for (R)-3-HB production; second, further screening of suitable genes needs to be performed.
Based on optimization of (R)-3-HB synthesis, thiolase gene (thl) from C. acetobutylicum and reductase gene (phaB) from C. necator were chosen to combine with PHA synthase gene (phaC) for creating the PHB-V producing strain. The PHA synthase expression module, containing TEF1 promoter and PHO5 terminator, was cloned into Xplor2 vector together with thiolase and reductase expression modules and used for A. adeninivorans transformation. The engineered strain accumulated up to 7.47% PHB of dcw. During the set of cells passaging A. adeninivorans lost the ability to accumulate polymer with maximal 23.1 % of primary accumulation level. Additionally, use of a vector including hygromycin B antibiotic resistance marker (instead of auxotrophic marker in Xplor2) did not improve polymer accumulation and stability.
To counteract the effect of loss of accumulation stability, phasin gene (phaP1), originated from C. necator, was introduce together with PHA pathway genes. First screening cultivations resulted in stabilizing of polymer production reaching 9.58 % PHB of dcw and only 12.0 % loss of production ability. Further experiments increased PHB content with 19.9% PHB of dcw (3.85 g L-1) after 180 h of cultivation using rich medium. Use of another thiolase gene, the second thiolase from C. necator (bktB), which theoretically should induce production of PHBV copolymer, led to accumulation only 11.4% PHB of dcw after 139 h and no PHV fraction was detected.
Variation of the ratio between flask volume and amount of media influences the level of aeration. Importantly, decrease of aeration level significantly increased polymer synthesis. Additionally, PHB-V copolymer accumulation has been induced by use of different carbon source co-substrates. Use of rich media supplemented with ethanol allow the strain with thl thiolase to accumulate up to 42.9 % PHB of dcw without PHV fraction and with bktB thiolase to 30.5 % PHB of dcw. Nevertheless, despite of lower total amount of polymer, supplementation with 1-propanol allow both strains to accumulate PHB-V copolymer with 7.30 %mol and 22.5 %mol of PHV for thl and bktB strains, respectively.
Optimization based on genetic engineering further enhanced polymer production yield led to exceeding of 50 % PHB-V of dcw. For doubling the gene dosage, PHA synthesizing strains of A. adeninivorans were again transformed with Xplor2 vector containing PHA pathway genes. Resulting strains exhibited twice the level of enzymatic activities of thiolase and reductase compared with strains transformed once with expression vector. In a shaking flask experiment the strain transformed twice with vector containing bktB thiolase reached after 240 h 52.1% PHB-V of dcw (10.8 g L-1) with 12.3 %mol of PHV fraction which is the highest level found in yeast. As another genetic approach, a fusion strain has been created. Two different strains have been established and merged using protoplast fusion technique. Doubling of genetic material resulted in similar level of copolymer produced by Arxula as in former experiments (50.2% of dcw, 10.7 g L-1).
Culture conditions were optimized in controllable cultivation using fed-batch mode. Although optimal oxygen and pH level and continuous carbon source and nitrogen feeding were maintained, final polymer level in % of dry mass was around three times lower than for shaking flask experiment. Nevertheless, efficient growth of Arxula in fed-batch mode led to increase of total copolymer level in g L-1 (16.5 g L-1 compare to 10.8 g L-1 for shaking flasks) showing the feasibility of using Arxula strain for up-scaling production of copolymer.
Acetyl-CoA is a main precursor in synthesis of PHB-V copolymer and change of its pool was investigated. ATP citrate lyase is a cytosolic enzyme converting citrate into oxaloacetate and acetyl-CoA, supporting the biosynthesis of fatty acids. Two genes encoding Acl subunits from Aspergillus nidulans (AnAcl1 and AnAcl2) were again cloned into Xplor2 vector and transformed into A. adeninivorans PHA producing strain. Despite of higher enzymatic activity of AnAclp, accumulation of polymer was around three times higher for control without expression of lyase genes. Expectedly, the strain expressing AnAcl1/2 genes accumulated larger amount of each stearic, palmitic and oleic acid in both standard and fatty acid inducing conditions (lower nitrogen level). Thus, overexpression of AnAcl1/2 genes in A. adeninevorans cells may improve biosynthesis of fatty acids but is ineffective for PHB polymer accumulation.
The aim of the project was use of starch-based media, manufactured as by-products, for polymer production. Genetically engineered Arxula strains were cultivated using these media instead of glucose-based media. Although yeast cells were both able to secrete (R)-3-HB and to accumulate PHB, the yield was lower than for previous media. Additionally, only trace of PHV was found at the end of cultivation time when 1-propanol was supplemented. Obtained results showed that use of cheaper media is a promising approach to decrease production costs but further optimization needs to be performed especially for extended scale of production.
Determination of produced copolymer has been done based on microscopic analysis and studies of physical and chemical properties. Results revealed that Arxula accumulated PHA polymer in cytosolic granules with a similar size range compared to the ones produced by bacteria. The physicochemical study showed that produced polymer exhibited slightly different properties in comparison to bacterial polymer with similar content of PHV, i.e. very-low molecular mass, higher melting and glass transition temperature.
All above results showed that A. adeninivorans is a promising host for PHB-V production. Expression of phasin greatly increased production and stability of polymer, which led to an accumulation level never found before in yeast. Further optimization in higher production scale using cheap starch-based media may establish Arxula strain as a valuable tool for industrial production of PHB-V copolymer.
This dissertation focusses on the numerical modelling of resonant destabilization of Alfvén eigenmodes by fast ions in fusion plasmas. It especially addresses non-linear simulations of stellarator plasmas in which particle collisions are retained. It is shown that collisions are required for a realistic description of Alfvén waves in plasmas relevant to nuclear fusion.
We start by carefully verifying the implementation of the collision operators into the electromagnetic version of the gyro-kinetic delta-f particle-in-cell code EUTERPE. After these initial benchmarks are completed successfully, the code is in a position to be applied to realistic tokamak and stellarator scenarios.
Since every collision operator needs to fulfil conservation laws, a momentum-conserving version of the pitch-angle scattering operator is implemented. This is in particular important for neoclassical transport simulations aimed at computing flux-surface variations of the electrostatic potential in stellarators.
Using the simplified CKA-EUTERPE model (employing a fixed-mode-structure approximation), we perform non-linear simulations in tokamaks and stellarators. We show that the non-linear dynamics of fast-ion-driven Alfvén eigenmodes is significantly influenced by collisions. They have the potential to enhance the saturation level and to affect the frequency chirping of the modes.
It is thus concluded that collisions play an essential role in determining Alfvén-eigenmode-induced fast-ion transport - an important issue for future fusion devices. In order to address this issue the CKA-EUTERPE model is extended to evolve multiple modes at the same time. First results of this multi-mode version (which enhances the level of realism of the simulations) are shown in the Appendix of the thesis.
Optomechanical (om) systems are characterized by their nonlinear light-matter interaction. This is responsible for unique dynamic properties and allows the detection of a variety of classical and quantum mechanical phenomena on a microscopic as well as on a macroscopic scale. In this work we have studied the dynamic behavior of two laser-driven om systems, the single om cell ("cavity optomechanics / membrane-in-the-middle setup") and a two-dimensional hexagonal array of these cells ("om graphene"). The first case was motivated by the possibility to detect the transition from quantum mechanics to classical mechanics directly on the basis of the dynamic behavior. For this we focus on multistability effects of the optical and mechanical degrees of freedom, that are modeled by harmonic oscillators. Our description is based on the quantum optical master equation, which takes into account the environmental interaction assuming a vanishing temperature. As a consequence of decoherence, the dynamics occur near the semiclassical limit, i.e. it is characterized by quantum fluctuations. The quantum-to-classical transition is realized formally by rescaling the equations of motion. In the classical limit, quantum fluctuations disappear and the mean field equations were evaluated by analytical and numerical methods. We found that classical multistability is characterized by stationary signatures on the route to chaos, as well as by the coexistence of single-periodic orbits for the mechanical degree of freedom. The latter point was extensively evaluated by means of a self-consistent approach. For the dynamics in the quantum regime quantum fluctuations cannot be neglected. For this purpose, the master equation was solved by means of a numerical implementation of the Quantum State Diffusion (QSD) method. Based on Wigner and autocorrelation functions, we were able to show that quantum multistability is a dynamic effect: chaotic dynamics is suppressed and there is a time-dependent distribution of the phase space volume on classical simple-periodic orbits. The results can be interpreted within a semiclassical picture, which makes use of the single QSD quantum trajectory. Accordingly, the quantum-classical transition is explained as a time-scale effect, which is determined by tunneling probabilities in an effective mean-field potential. The subject of the second part of the work is the transport of low-energy Dirac quasiparticles in om graphene, propagating as light and sound waves. For this purpose, we investigated the scattering of a plane light wave by laser-induced photon-phonon coupling planar and circular barriers. The starting point is the om Dirac equation, which results from the continuum approximation of the Hamiltonian description of the two-dimensional array near the semiclassical limit. This work was motivated by the rich and interesting relativistic transport and tunneling phenomena found for electrons in graphene, which now appear in a new way. The reason is the presence of the new spin degree of freedom, which distinguishes the optical and mechanical excitations. In this spin space, the om interaction can be understood as a potential, which in our analysis consists of a time-independent and a time-dependent sinusoidal part. For the first case of a static barrier, the transport is elastic and is characterized by stationary scattering signatures. After solving the scattering problem via continuity conditions we were able to identify different scattering regimes depending on scattering parameters. In addition to relativistic phenomena such as Klein tunneling, simple parameter variation allows to use the barrier as a resonant light-sound interconverter and angle-dependent emitter. For the oscillating barrier, the transport is inelastic and is characterized by dynamic scattering signatures. To solve the time-periodic scattering problem, we have applied the Floquet theory for an effective two-level system. As a result of the barrier oscillation, photons and phonons can get and give away energy portions in the form of integer multiples of the oscillation frequency. The interference of short (classical) and long-wave (quantum) components leads to mixing of the scattering regimes. This allows to use the barrier as a time-periodic light-sound interconverter with interesting radiation characteristics. In addition, we have argued that the oscillating barrier provides the necessary energetic conditions for detecting zitterbewegung.
Amine transaminases are versatile biocatalysts for the production of pharmaceutically and agrochemically relevant chiral amines. They represent an environmentally benign alternative to waste intensive transition metal catalysed synthesis strategies, especially because of their high stereoselectivity and robustness. Therefore, they have been frequently used in the (chemo)enzymatic synthesis of amines and/or became attractive targets for enzyme engineering especially in the last decade, mainly in order to enlarge their substrate scope. Certainly, one of the most notable examples of amine transaminase engineering is the
manufacturing of the anti-diabetic drug Sitagliptin in large scale after several rounds of protein engineering. Thereby, the target amine was produced in asymmetric synthesis mode which is the most convenient and favored route to a target chiral amine, starting from the corresponding ketone. The choice of the amine donor is highly relevant for reaction design in terms of economical and thermodynamic considerations. For instance, the use of alanine as the natural amine donor is one of the most common strategies for the amination of target ketones but needs the involvement of auxiliary enzymes to shift the reaction equilibrium towards product formation. In fact, isopropylamine is probably one of the most favored donor molecules since it is cheap and achiral but it is supposed to be accepted only by a limited number of amine transaminases.
This thesis focusses on the optimization and application of amine transaminases for asymmetric synthesis reactions en route to novel target chiral amines using isopropylamine as the preferred amine donor.
Sexual selection favours traits that confer a competitive advantage in access to mates and to their gametes. This results in males evolving a wide array of adaptations that may be conflictual with female’s interests and even to collateral negative effects on female’s lifespan or reproductive success. Harmful male adaptations are diverse and can be extreme. For example, males of various species evolved adaptations that incur physical damage to the female during copulation, referred to as traumatic mating. Most of these adaptations provide males with a competitive fertilization advantage due to the injection of sperm or non-sperm compounds through the wound. In the spider taxonomical literature, alterations of external genital structures have been reported in females and may result from male inflicted damage during copulation. Contrarily to other cases of traumatic mating, the transfer of sperm or non-sperm compounds does not seem to be the target of selection for external female genital mutilation (EFGM) to evolve. Therefore, investigating EFGM may provide valuable information to extend our understanding of the evolution of harmful male adaptations. In this thesis, I explore this newly discovered phenomenon and combine empirical and theoretical approaches to investigate the causes and consequences of EFGM evolution from male and female perspectives. My findings suggest that EFGM is a natural phenomenon and is potentially widespread throughout spider taxa. I demonstrate the proximal mechanism by which the male copulatory organ mutilates the external female genitalia during genital coupling and show that the mutilation results in full monopolization of the female as mutilated females are unable to remate. Using a theoretical approach, I investigated the conditions for the evolution of EFGM. The model developed suggests that EFGM evolution is favoured for last male sperm precedence and for costs to females that can be relatively high as the male-male competition increases. I present the results of physiological measurements that suggest there is no physiological cost of genital mutilation resulting from healing and immune responses for the female. Finally, I report the results of a behavioural experiment that suggest that females have control over the mutilation and selectively allow or avoid mutilation. These findings suggest that EFGM benefits males by securing paternity, that males and females may have evolved to reduce the costs incurred by the female and that female choice may also play a role in EFGM evolution.
The Effect of the Patients Nutritional Status on Immune Alterations Induced by Ischemic Stroke
(2018)
Ischemic stroke is one of the leading causes of death and disability throughout the world.
One important aspect of stroke pathophysiology are immunological changes after stroke, especially a combination of post stroke immunodepression, leading to
infectious complications after stroke and an activation of the immune system, leading to cerebral injury. Adipose tissue has several immunological functions and obesity
leads to immunological complications and is accompanied by a chronic immune activation.
To study the effects of body weight and obesity on the immune system and measure weight and fat tissue changes after ischemic stroke we conducted the LIPS Trial and enrolled 50 stroke patients and 16 control subjects between July 2015 and July 2016. On the day of admission and on the days 1, 2, 3, 4, 5, 7, 30, 90 and 180 after admission stroke patients were weighed with an in-bed scale, body composition was measured with BIA, the triceps-skin fold thickness was measured, the NIHSS scale was obtained and blood was drawn. FACS-analysis was performed and triglycerides,cholesterol, CRP and PCT were measured at the central laboratory facility of the Universitätsmedizin Greifswald. Luminex-multiplex analysis for multiple cyto- and chemokines was performed at the Multiplex Facility at the University Leiden. A cerebral MRI and an abdominal MRI were performed shortly after admission and on days 5-7 for most patients and the infarct volume, abdominal fat and hepatic fat percentage were measured. On days 30, 90 and 180 after stroke Bartel Index and mRS were obtained.
After stroke our patients showed the typical immunological changes described previously as stroke induced immune alterations, namely a post stroke immunodepression as well as signs of an activated immune system and an acute
phase response. Our patients lost weight, but only 1.7 ± 0.5 kg. Skinfold thickness did not change during the course of our trial and abdominal fat measurement did not change in stroke patients. Immunological parameters (leukocytes, neutrophils,CRP, PCT, IL-6) did not differ between BMI subgroups (normal weight: BMI < 25,overweight: BMI ≥ 25, < 30, obese: BMI ≥ 30) and in this trial we could not detect a
difference in patients with normal weight, overweight or obesity in the post stroke periode. In an additional analysis we could show that rapid clinical improvement
did result in a rapid improvement of post stroke immune alterations, especially for leukocytes, neutrophils, IL-6 and CRP.
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.
Rabies virus (RABV) is an ancient, highly neurotropic rhabdovirus that causes lethal encephalitis. Most RABV pathogenesis determinants have been identified with laboratory-adapted or attenuated RABVs, but details of natural RABV pathogenesis and attenuation mechanisms are still poorly understood. To provide a deeper insight in the cellular mechanism of pathogenies of field RABV, this work was performed to assess virus strain specific differences in intra-neuronal virus transport, to identify cell culture adaptive mutations in recombinant field viruses and to explore shRNA-expressing RABVs as research tools for targeted host manipulation in infected cells.
Comparison of chimeric RABVs with glycoprotein (G) ecto-domains of different lyssaviruses, together with field RABVs from dog and fox in dorsal root ganglion (DRG) neurons revealed no detectable differences in the axonal accumulation of the viruses. This indicates that previously described G-dependent transport of newly formed RABV in axons can occur both in laboratory-adapted and field RABV. Moreover, partial overlap of nucleoprotein (N) and G protein particles in field virus infected DRG axons supported the hypothesis of the “separate model” for anterograde RABV transport.
Serial passages of recombinant dog and fox field clones in different cell lines led to the identification of general (D266N) and cell line specific (K444N) adaptive mutations in the G ecto-domain of both viruses. In BHK cells, synergistic effects of D226N, K444N and A417T on field dog virus G protein surface localization led to the loss of endoplasmic reticulum (ER) retention of G and increased virus titers in the supernatant, indicating that limited virus release by ER retention is a major bottleneck in cell culture adaptation. In addition, selection of mutations within the C-terminus of the RABV phosphoprotein (P) (R293H and R293C in fox and dog viruses, respectively) led to the hypothesis of altered binding affinities to nucleoprotein and RNP complexes. Identification of the above mentioned amino acid substitutions together with alterations in a suboptimal transcription stop signal in the P/M gene border indicated that adaptation to cell culture replication occurs on both levels, RNA transcription/replication and virus release.
To evaluate the possibility of an expression of a functional microRNA-adapted short-hairpin RNAs (miR-shRNA) expressing RABV, recombinant RABVs encoding miR-shRNAs against cellular Dynein Light Chain 1 (DYNLL1) and Acidic Nuclear Phosphoprotein 32 family member B (ANP32B) were generated. In spite of cytoplasmic transcription of the respective mRNAs, downregulation of DYNLL1 and ANP32B mRNA and respective protein levels in infected cells revealed correct processing to functional shRNAs. Specific downregulation of the cellular genes at 2, 3 and 4 days post infection further demonstrated feasibility of the approach in standard cell lines. However, it remained open whether miR-shRNA expressing RABV can be used to study neuro-infection in vivo. Since first attempts in primary rat neuron cultures failed, it has to be clarified in further experiments whether this strategy can be used in mature, non-dividing neurons or whether breakdown of the nucleus in the course of cell division is a requirement for the processing of cytoplasmically expressed miR-RNA by nuclear RNases.
By providing novel insights in axonal RABV transport and cell culture adaptive mutations this work extends the current understanding of RABV pathogenesis in natural and non-natural cell environments. Moreover, it provides a basis for further pathogenicity studies in which the impact of cell culture adaptation through increased virus release on RABV virulence can be investigated. With successful expression of functional miR-shRNAs from RABV vectors, this work also provides a tool for RABV gene targeting in infected cell lines and thus may contribute to the further investigation of RABV-host-cell-interactions.
Functional characterization of a novel protease isolated from a mouse-adapted S. aureus strain
(2018)
Background: The high incidence of methicillin-resistant Staphylococcus aureus
(MRSA) strengthens the need for new effective antibiotics and a protective vaccine. Up till now, mainly human-adapted Staphylococcus aureus strains were used to study S. aureus pathogenicity in mouse models. However, it is known that S. aureus is highly host-specific. Recently, a mouse-adapted S. aureus strain, JSNZ, was identified. This strain could be a promising tool in developing more appropriate infection models. JSNZ produces high amounts of a putative extracellular protease, named JSNZ extracellular protease (Jep). Since the jep gene was only detected in S. aureus isolates from laboratory mice and wild small rodents and shrews, we hypothesize that Jep is important for colonization and infection in mice. The jep deletion mutant previously created by our collaborators from the University of Auckland, New Zealand, intriguingly showed a reduced survival and growth fitness in murine serum and whole blood as compared to the JSNZ wild type (WT) strain.
Objective: To elucidate the role of Jep in the interaction between S. aureus and its
host by comparing the impact of JSNZ WT with a mutant and a complement strain on the murine immune system. In addition, the elucidation of possible genetic factors behind host-adaptation of S. aureus strains isolated from wild rodents and shrews.
Methods: A jep complemented strain was generated by chromosomal replacement.
JSNZ WT, the jep mutant and the complement strain were subjected to functional
assays (whole blood survival assay, coagulation assay). In addition, the genetic
background that might confer host specificity was tested by staph array genotyping.
Results: The mutant strain JSNZDjep was successfully complemented with the jep
gene using a chromosomal integration approach. The WT strain and the
complemented strain produced the Jep protein in comparable amounts.
Unexpectedly, the complemented strains did not behave like the WT strain but rather like the mutant in a series of in vitro assays. Firstly, the growth of both the deletion mutant and the complemented strains was slightly reduced in TSB as compared to the WT strain. Secondly, the jep knockout strain showed a strongly reduced survival in murine whole blood compared to its wild type counterpart, but so did the complemented strain. Finally, the coagulation of murine plasma was less pronounced for the jep deletion mutant and the complemented strain as compared to the JSNZ WT. To exclude a defect in jep gene expression, we compared the amount of Jep expressed during growth in TSB medium for the three strains. The complemented strain produced Jep in a manner similar to the WT strain in a growth-phase dependent manner, suggesting that Jep expression was not affected during the creation of the complemented strain.
The array data showed some differences in the genetic makeup between animal
isolated strains and matched human strains. For example, while all animal isolates of the CC88 lacked the resistance mecA gene it was found in some human isolates of the same strain.
Conclusion: In conclusion, our unidentified mutation created during the generation
of the jep knock-out strain rather than the jep gene itself manipulated the murine
immune response. The responsible gene and the underlying mechanisms remain to
be clarified. Genetic profiling of S. aureus strains allowed us to obtain some valuable information including data about CC49, the most frequently isolated lineage in wild rodents and shrews where compared to the human isolates the murine strains showed clear signs of host adaptation. However, the analysis had several limitations including the small sample size.
The Flavivirus genus (Flaviviridae family) comprises the most important arboviruses in the world such as dengue virus, West Nile virus (WNV), Zika virus (ZIKV), Japanese encephalitis virus and yellow fever virus (YFV). Every year, several outbreaks caused by flaviviruses are reported worldwide (i.e.: ZIKV and YFV outbreaks in South America) with a huge impact on economy and public health. In the last few decades, many aspects of the flavivirus biology and the interaction of flaviviruses with host cells have been elucidated. However, many underlying mechanisms concerning receptor usage, entry process and viral interaction with host cell factors are still not completely understood. Integrins, the major class of cell adhesion molecules have been implicated in the infectious cycle of different viruses including flaviviruses. A previous report proposed that a particular integrin, the αVβ3 integrin, might act as a cellular receptor for WNV. However, this hypothesis was not confirmed by other groups. In the present study, murine cell lines lacking the expression of one or more integrin subunits were used to evaluate the involvement of different integrins in the flavivirus infection cycle. Mouse fibroblasts lacking the expression of β1 integrin (MKF-β1-/-) or β3 integrin (MEF-β3-/-) subunits or αVβ3 integrin (MEF-αVβ3-/-) as well as their corresponding wild-type cells were utilized. A second model using Chinese hamster ovary cells (CHO-K1), a cell line that has been described to be refractory to some flaviviruses, were modified to express either αV (CHO-αV+/+) or β3 (CHO-β3+/+) integrin subunits. All cell lines were first characterized by confocal laser microscopy, flow cytometry and functional assays prior to infection to assess their integrin expression. The cell lines were then inoculated with different flaviviruses of public health relevance: WNV, YFV-17D, Usutu virus (USUV), Langat virus (LGTV) and ZIKV. Infection assays were designed in order to evaluate whether integrins influence i) cell susceptibility; ii) binding; iii) internalization and iv) replication of the investigated flaviviruses. Our findings clearly demonstrate that β1, β3 and αVβ3 integrins do not act as flavivirus cellular receptor or attachment factor since their ablation does not completely abrogate flavivirus infection in the investigated cell lines. Flavivirus binding to the cell surface of MEFs, MKFs and CHO cells was not disturbed by the genomic deletion of the above-mentioned integrins. The deletion of β1 and β3 integrin subunit did not affect internalization of any of the flaviviruses tested. In contrast to that, loss of αVβ3 integrin in the MEF-αVβ3-/- cells showed a statistically significant decrease in WNV and USUV internalization while ZIKV, YFV-17D and LGTV internalization remained unaffected suggesting that αVβ3 integrin might be involved in the internalization process of at least some flaviviruses. On the other hand, flavivirus replication was substantially impaired in the integrin-deficient cell lines in comparison to their corresponding wild-type cells. Both, MEF-β3-/- and MKF-β1-/- cells showed a statistically significant reduction on viral load for all flaviviruses tested in comparison to their respective wild-type cells. The MEF-αVβ3-/- cells in particular, showed a strong inhibition of flavivirus replication with a reduction of up to 99% on viral loads for all flaviviruses tested. Levels of flavivirus negative-strand RNA were substantially decreased in MEF-αVβ3-/- cells indicating that integrins might influence flavivirus RNA replication. The ectopic expression of either αV or β3 integrin subunits in CHO cells slightly increased the replication of all flaviviruses tested. Taken together, this is the first report highlighting the involvement of integrins in ZIKV, USUV, LGTV and YFV infection. The results strongly indicate that the investigated integrins play an important role in flavivirus infection and might represent a novel host cell factor that enhances flavivirus replication. Although the exact mechanism of interaction between integrins and flaviviruses is currently unknown, the results provided in this study deepen our insight into flavivirus - host cell interactions and open doors for further investigations.
Self-affine tiles and fractals are known as examples in analysis and topology, as models of quasicrystals and biological growth, as unit intervals of generalized number systems, and as attractors of dynamical systems. The author has implemented a software which can find new examples and handle big databases of self-affine fractals. This thesis establishes the algebraic foundation of the algorithms of the IFStile package. Lifting and projection of algebraic and rational iterated function systems and many properties of the resulting attractors are discussed.
Glacitectonic deformation in the Quaternary caused the tectonic framework of large-scale folds and displaced thrust sheets of Maastrichtian (Upper Cretaceous) chalk and Pleistocene glacial deposits in the southwestern Baltic Sea area.
A wide spectrum of methods has been compiled to unravel the structural evolution of the Jasmund Glacitectonic Complex. The analyses of digital elevation models (DEM) suggest a division into two structural sub-complexes – a northern part with morphological ridges striking NW–SE and a southern part with SW–NE trending ridges. Geological cross sections from the eastern coast (southern sub-complex) were constructed and restored using the software Move™ and the complementary module 2D Kinematic Modelling™.
The final geometric model of the southern sub-complex shows a small-scale fold-and-thrust belt. It includes three different orders of architectural surfaces (see PEDERSEN, 2014): erosional surfaces and the décollement (1st order), thrust faults (2nd order), and beds outlining hanging-wall anticlines as well as footwall synclines (3rd order). Thrust faults of the southern structural sub-complex are mainly inclined towards south, which indicates a local glacier push from the S/SE.
The glacitectonic structures have a surface expression in form of sub-parallel ridges and elongated valleys in between. Geomorphological mapping and detailed landform analyses together with the structural investigations provide an insight into the chronology of sub-complexes formation. The northern part of the glacitectonic complex is suggested to have been formed before the southern one, considering the partly truncated northerly ridges and their superimposition by the southern sub-complex.
Although there is a high number of scientific publications on the glacitectonic evolution of Jasmund, these presented models often lack a consistent theory for the development integrating all parts of the 100 km2 large complex. Therefore, the combination of all results leads to a more self-consistent genetic model for the entire Jasmund Glacitectonic Complex.
Herpesviruses are a fascinating group of enveloped DNA viruses, which rely on membrane fusion for infectious entry and direct cell-to-cell spread. Compared with many other enveloped viruses, they utilize a remarkably complex fusion machinery. Three conserved virion proteins, the bona fide fusion protein gB, and the presumably gB activating gH/gL heterodimer constitute the conserved core fusion machinery and are believed to drive membrane fusion in a cascade-like fashion. Activation of this cascade in most alphaherpesviruses is proposed to be triggered by binding of gD to specific host cell receptors. The molecular details of this fusion process, however, remain largely elusive. Yet, a detailed mechanistic knowledge of this process would be greatly beneficial for the development of efficient countermeasures against a variety of diseases. In this thesis, the functional relevance of individual components of the essential gH/gL complex of the alphaherpesvirus PrV has been assessed by two different approaches: by reversion analysis (paper II) and site-directed mutagenesis (papers III-V). In contrast to other herpesviruses, gL-deleted PrV is able to perform limited cell-to-cell spread, providing the unique opportunity to passage the entry-deficient virus in cell culture to select for PrV revertants capable of infecting cells gL-independently. This approach already resulted in an infectious gL-negative PrV mutant (PrV-ΔgLPass), in which the function of gL was compensated by formation of a gDgH hybrid protein. Here, the requirements for gL-independent infectivity of a second independent revertant (PrV-ΔgLPassB4.1), were analyzed. Sequencing of the genes encoding for gB, gH and gD, revealed mutations in each of them. By means of a robust infection-free, transfection-based cell-cell fusion assay (paper I), we identified two amino acid substitutions in the gL-binding domain I of gHB4.1 (L70P, W103R) as sufficient to compensate for lack of gL. Two mutations in gB (G672R, ΔK883) were found to enhance fusogenicity, probably by lowering the energy, required for gB refolding from pre- to postfusion conformation. Coexpression of gHB4.1 and gBB4.1 led to an excess fusion, which was completely suppressed by gDB4.1 in the fusion assays. This was surprising since PrV gD is normally not required for in vitro fusion or direct viral cell-to-cell spread, clearly separating this process from fusion during entry, for which PrV gD is essential. The fusion inhibiting effect of gDB4.1 could be attributed to a single point mutation resulting in an amino acid substitution within the ectodomain (A106V). In conclusion, these results indicated that gL is not central to the fusion process, as its function can be compensated for. As found so far, gL-independent infectivity can be realized by compensatory mutations in gH (as in PrV-ΔgLPass) or in gH plus gB (as in PrV-ΔgLPassB4.1). Excessive fusion induced by gHB4.1 and gBB4.1 was counter-regulated by gDB4.1, indicating that the interplay between these proteins is precisely regulated and further implies that gL and gD, despite being not absolutely essential for the fusion process, have important regulatory functions on gH and/or gB.
Both PrV-ΔgLPass mutants had acquired compensatory mutations in gH affecting the predicted gL-binding domain I in gH. By construction of an artificial gH32/98, which lacked the predicted gL-binding domain and was similar to the recently crystallized gH-core fragment present in the gDgH hybrid protein, we identified the N-terminal part of PrV gH as essential for gH function during fusion (paper III). gH32/98 was unable to promote fusion of wild-type gB in fusion assays and led to a total loss of function in the viral context. These results indicated that the gD moiety, present in gDgH, is critical for proper function of the gH-core fragment. We hypothesize that the gD moiety may adopt a stabilizing or modulating influence on the gH structure, which is normally executed by gL and important for interaction of gH with wild-type gB. Remarkably, substitution of wild-type gB by gBB4.1 rescued function of gH32/98 in the cellular and viral contexts. These findings suggest that gBB4.1 has been selected for interaction with “gL-less” gH. In conclusion, these results demonstrated that gL and the gL-binding domain are not strictly required for membrane fusion during virus entry and spread but that compensatory mutations must be present in gB to restore a fully functional fusion machinery. These results strongly support the notion of a functional gH-gB interaction as a prerequisite for membrane fusion.
In addition to the N-terminal domain, we identified the transmembrane domain of PrV gH as an essential component of the fusion machinery, while the cytoplasmic domain was demonstrated to play a modulatory but nonessential role (paper IV). Whereas truncation or substitution of the PrV gH TMD by a gpi-anchor or the analogous sequence from PrV gD rendered gH non-functional, the HSV-1 gH TMD was found to functionally substitute for the PrV gH TMD in cell-cell fusion and complementation assays. Since residues in the TMD which are conserved between HSV and PrV gH but absent in PrV gD, are placed on one face of an α-helical wheel plot, we hypothesize that the gH TMD has an intrinsic property to interact with membrane components such as lipids or other molecules as a requirement for promoting membrane fusion.
In a final study focusing on the function of gH, we identified the N-glycosylation sites utilized by PrV gH, and determined their individual role in viral infection (paper V). PrV gH was found to be modified by N-glycans at five potential glycosylation sites. N-glycans at PrV specific N77 and the highly conserved site N627 were found to be critical for efficient membrane fusion in the fusion assays, and during viral entry and cell-to-cell spread. N627 was further shown to be crucial for proper gH transport and maturation. In contrast, inactivation of N604, conserved in the Varicellovirus genus, enhanced in vitro fusion activity and viral cell-to-cell spread. These findings demonstrated a role of the N-glycans in proper localization and function of PrV gH.