Universität Stuttgart

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    Precision 3D‐printed cell scaffolds mimicking native tissue composition and mechanics
    (2020) Erben, Amelie; Hörning, Marcel; Hartmann, Bastian; Becke, Tanja; Eisler, Stephan A.; Southan, Alexander; Cranz, Séverine; Hayden, Oliver; Kneidinger, Nikolaus; Königshoff, Melanie; Lindner, Michael; Tovar, Günter E. M.; Burgstaller, Gerald; Clausen‐Schaumann, Hauke; Sudhop, Stefanie; Heymann, Michael
    Cellular dynamics are modeled by the 3D architecture and mechanics of the extracellular matrix (ECM) and vice versa. These bidirectional cell‐ECM interactions are the basis for all vital tissues, many of which have been investigated in 2D environments over the last decades. Experimental approaches to mimic in vivo cell niches in 3D with the highest biological conformity and resolution can enable new insights into these cell‐ECM interactions including proliferation, differentiation, migration, and invasion assays. Here, two‐photon stereolithography is adopted to print up to mm‐sized high‐precision 3D cell scaffolds at micrometer resolution with defined mechanical properties from protein‐based resins, such as bovine serum albumin or gelatin methacryloyl. By modifying the manufacturing process including two‐pass printing or post‐print crosslinking, high precision scaffolds with varying Young's moduli ranging from 7‐300 kPa are printed and quantified through atomic force microscopy. The impact of varying scaffold topographies on the dynamics of colonizing cells is observed using mouse myoblast cells and a 3D‐lung microtissue replica colonized with primary human lung fibroblast. This approach will allow for a systematic investigation of single‐cell and tissue dynamics in response to defined mechanical and bio‐molecular cues and is ultimately scalable to full organs.
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    Construction of robust Escherichia coli strains for large-scale production
    (2022) Ziegler, Martin; Takors, Ralf (Prof. Dr.-Ing.)
    The biotechnical production of many fine chemicals, proteins or pharmaceuticals depends on large-scale microbial cultivations. Due to limited mixing, heterogeneities in process relevant parameters such as nutrient concentrations arise in such fermentations. Escherichia coli (E. coli) is a model organism frequently used in the biotechnological industry. If E. coli is cultivated under heterogeneous conditions, biological reactions of the microorganism result in reduced process performance. Since large-scale fermentations are not economically feasible in academic settings, scale-down reactors that mimic aforementioned heterogeneities are used to investigate heterogenous fermentations. Previous studies in scale-down reactors unraveled that, depending on the process strategy, the unstable supply of a limiting primary carbon or nitrogen source such as glucose or ammonium is one of the underlying causes of process performance loss. Low concentrations of glucose or ammonium elicit the stringent response as a biological starvation reaction which comprises extensive transcriptional reactions. In the first project that contributes to this thesis, the regulatory and transcriptional reactions of the strains E. coli MG1655 and E. coli SR to repeated exposure to ammonium starvation zones were examined in a scale-down reactor. The scale-down reactor followed a two-compartment approach and consisted of a stirred tank reactor and a plug-flow reactor simulating passage through a starvation zone. E. coli SR is a strain with modulated stringent response. It was observed that short-term starvation stimuli do not trigger this regulatory program in E. coli SR and the transcriptional reaction was noticeably reduced. Long-term adaptation of the strain to repeated cycles of limitation and starvation also clearly differed from E. coli MG1655. Despite lack of the stringent response, E. coli SR showed no deficits in the assimilation of the limiting ammonium or in biomass yield on ammonium. In the second project of this thesis, a series of deletion strains with robust phenotype against glucose starvation zones were constructed. Candidate genes were identified and successively removed from the genome of E. coli MG1655 by Recombineering. The fundamental growth parameters of the strains were determined in shaking flask fermentations and no noticeable differences compared to E. coli MG1655 were found. Chemostat cultivations in a scale-down reactor with glucose as the limiting nutrient source revealed that the final strain of the deletion series, E. coli RM214, had a significantly lower maintenance coefficient under heterogeneous conditions than E. coli MG1655. Moreover, in an exemplary heterologous protein productionscenario E. coli RM214 rhaB- pJOE4056.2_tetA proved to be more robust to heterogeneities and showed a significantly higher product yield than E. coli MG1655 rhaB- pJOE4056.2_tetA. In the third project of this thesis, the production of pyruvate in E. coli MG1655 by inhibition of pyruvate dehydrogenase through CRISPR interference was investigated. A central goal was to achieve the stable production in nitrogen-limited conditions. For this, different target sequences in the operon pdhR-aceEF-lpd were tested and the strains cultivated in shaking flask fermentations. All tested target sequences were generally suitable to trigger the accumulation of pyruvate. Combined CRISPR interference against two target sequences did not lead to an increased pyruvate yield in most cases. In addition, the strains E. coli MG1655 pdCas9 psgRNA_aceE_234 and E. coli MG1655 pdCas9 psgRNA_aceE_234_pdhR_329 were characterized in two phase fermentations in lab-scale reactors. The initial phase was an unlimited exponential growth phase and was followed by an ammonium-limited production phase. E. coli MG1655 pdCas9 psgRNA_aceE_234 only produced pyruvate during the exponential phase, and reuptake of pyruvate occurred in the second phase. In contrast, E. coli MG1655 pdCas9 psgRNA_aceE_234_pdhR_329 stably produced pyruvate during the exponential and the ammonium-limited phase and is a potential chassis strain for the growth-decoupled production of pyruvate derived bioproducts. The overarching research issues of the projects were the characterization of strains in heterogeneous conditions and the development of new strategies to improve their performance. The collected data leads me to conclude that the construction of robust microbial strains for large-scale applications is both expedient and feasible. Tailored genetic modifications are the method of choice to achieve this goal. Furthermore, suitable genetic constructs offer promising possibilities for the stable growth-decoupled production of chemicals in nitrogen-limited conditions.
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    Lokalisation, Speicherung und Synthese von Polyphosphat in Agrobacterium tumefaciens C58
    (2021) Hellenbroich, Celina; Jendrossek, Dieter (apl. Prof. Dr. rer. nat.)
    Polyphosphat (PolyP) besitzt eine ubiquitäre Verbreitung und erfüllt, je nach Organismus, unterschiedliche und extrem vielfältige Aufgaben. In Prokaryonten liegt PolyP in sogenannten Granula vor, während in einzelligen Eukaryonten, eine Membran das PolyP von dem Cytoplasma abtrennt. Vorangegangene Arbeiten weisen darauf hin, dass sogenannte Acidocalcisomen, eben jene membranumschlossene PolyP-Speicher aus Eukaryonten, auch in dem Bodenbakterium Agrobacterium tumefaciens vorhanden sein könnten. Die vorliegende Arbeit zeigt jedoch, dass sich in A. tumefaciens, wie in Bakterien übliche, PolyP-Granula befinden, die nicht von einer Membran umschlossen sind. Im weiteren Verlauf wurde die Synthese von PolyP sowie die Lokalisation der Polyphosphatkinasen (PPKs) und anderer aus der Literatur bekannter, PolyP-assoziierter Proteine untersucht. Die PPK1At stellte sich hierbei als PolyP-Syntheseenzym heraus. Es folgte eine biochemische Charakterisierung der PPKs in vitro, bei der für die PPK2At, neben der Bildung von NDP und NTP, eine oligophosphorylierende Funktion bis hin zu nonaphosphorylierten Nukleosiden entdeckt wurde. Außerdem stellte sich heraus, dass das PolyP-Granulum während des Zellzyklus wanderte und vielleicht durch die PPK1At mit der DNA assoziiert sein könnte. Aufgrund dieser Erkenntnisse konnte ein Modell des PolyP-Granulums und den in dieser Arbeit identifizierten, assoziierten Proteinen erstellt werden. Eine Deletion der ppk1 hatte zudem Auswirkungen auf die Zellmorphologie, die Infektionsrate von Pflanzenzellen und die Generationszeit von A. tumefaciens.
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    Physical interactions strengthen chemical gelatin methacryloyl gels
    (2019) Rebers, Lisa; Granse, Tobias; Tovar, Günter E. M.; Southan, Alexander; Borchers, Kirsten
    Chemically cross-linkable gelatin methacryloyl (GM) derivatives are getting increasing attention regarding biomedical applications. Thus, thorough investigations are needed to achieve full understanding and control of the physico-chemical behavior of these promising biomaterials. We previously introduced gelatin methacryloyl acetyl (GMA) derivatives, which can be used to control physical network formation (solution viscosity, sol-gel transition) independently from chemical cross-linking by variation of the methacryloyl-to-acetyl ratio. It is known that temperature dependent physical network formation significantly influences the mechanical properties of chemically cross-linked GM hydrogels. We investigated the temperature sensitivity of GM derivatives with different degrees of modification (GM2, GM10), or similar degrees of modification but different methacryloyl contents (GM10, GM2A8). Rheological analysis showed that the low modified GM2 forms strong physical gels upon cooling while GM10 and GM2A8 form soft or no gels. Yet, compression testing revealed that all photo cross-linked GM(A) hydrogels were stronger if cooling was applied during hydrogel preparation. We suggest that the hydrophobic methacryloyl and acetyl residues disturb triple helix formation with increasing degree of modification, but additionally form hydrophobic structures, which facilitate chemical cross-linking.
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    Enzymatic asymmetric dihydroxylation of alkenes
    (2016) Gally, Christine; Hauer, Bernhard (Prof. Dr.)
    The introduction of chirality into C=C double bonds is of special interest in organic synthesis. In particular, the catalytic asymmetric dihydroxylation (AD) of alkenes has attracted considerable attention due to the facile transformation of the chiral diol products into valuable derivatives. By chemical means, the metal-catalyzed AD of olefins provides both stereo- and regiospecific cis-diol moieties. Next to their toxicity, however, these metal catalysts can also lead to byproduct formation as a result of oxidative fission. In nature, Rieske non-heme iron oxygenases (ROs) represent promising biocatalysts for this reaction since they are the only enzymes known to catalyze the stereoselective formation of vicinal cis-diols in one step. ROs are key enzymes in the degradation of aromatic hydrocarbons and can target a wide variety of different arenes. Despite their broad substrate scope, limited data is available for the conversion of unnatural substrates by this class of enzymes. To explore their potential for alkene oxidation, three ROs were tested for the oxyfunctionalization of a set of structurally diverse olefins including linear and cyclic arene-substituted alkenes, cycloalkenes as well as several terpenes. Naphthalene- (NDO), benzene- (BDO) and cumene dioxygenases (CDO) from different Pseudomonas strains where selected as they are amongst the RO enzymes that have already been reported to catalyze the oxidation of a small number of olefins. The majority of compounds from the selected substrate panel could be converted by NDO, BDO or CDO and products were either isolated and identified by NMR analysis or using the authentic standards. Dependent on the substrate, allylic monohydroxylation was found in addition to the corresponding diol products, a reaction which is chemically still most reliably achieved by the use of SeO2 in stoichiometric amounts. However, having been evolved for the dihydroxylation of aromatic compounds, wild type ROs displayed low conversions (< 50%) and modest stereoselectivities (≤ 80% ee/de) for several of the tested olefins. To overcome these limitations, changes in the active site topology of RO catalysts were introduced. A single targeted point mutation that was identified based on sequence and structural comparisons with other members of the RO family proved to be sufficient to generate BDO and CDO variants displaying remarkable changes in regio- and stereoselectivity for various substrates. In particular biotransformations with CDO M232A gave excellent stereoselectivities (≥ 95% ee/de) and good activities (> 90%) also for linear alkenes, which have been reported to be challenging substrates for RO-catalyzed oxyfunctionalizations. Site-saturation mutagenesis at position 232 in CDO revealed a correlation between the steric demand of the amino acid side chain and its influence on regio- and/ or stereoselectivities for styrene and indene. While the wild type enzyme almost exclusively catalyzed the dihydroxylation of the aromatic ring, the regioselectivity was shifted with decreasing side chain size to the terminal vinyl group of styrene, yielding up to 96% of the alkene-1,2-diol. For cis-1,2-indandiol formation, enantiocomplementary enzymes could be generated, a fact further highlighting the importance of position 232 for the engineering of ROs. Moreover, site-saturation mutagenesis of additional residues in the substrate binding pocket of CDO (F278, I288, I336 and F378) identified further positions having an influence on selectivity and product formation for alkene oxidation. To proof the applicability of ROs for organic synthesis, semi-preparative scale biotransformations (70 mg) of selected substrates were performed with CDO M232A. Without further optimization of the reaction set-up, products were successfully isolated in > 30% yield. In addition, up-scaling of (R)-limonene hydroxylation to 4 L in a bioreactor with growing cells gave final isolated product titers of 0.4 g L-1 even though substrate volatility and product toxicity diminished the yield. In conclusion, these examples demonstrated that a single point mutation was sufficient to transform CDO wild type into an efficient catalyst, furthermore constituting the first example of the rational engineering of CDO and BDO enzymes for the oxyfunctionalization of a broad range of alkenes.
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    Peptide controlled shaping of biomineralized tin(II) oxide into flower-like particles
    (2019) Kilper, Stefan; Jahnke, Timotheus; Wiegers, Katharina; Grohe, Vera; Burghard, Zaklina; Bill, Joachim; Rothenstein, Dirk
    The size and morphology of metal oxide particles have a large impact on the physicochemical properties of these materials, e.g., the aspect ratio of particles affects their catalytic activity. Bioinspired synthesis routes give the opportunity to control precisely the structure and aspect ratio of the metal oxide particles by bioorganic molecules, such as peptides. This study focusses on the identification of tin(II) oxide (tin monoxide, SnO) binding peptides, and their effect on the synthesis of crystalline SnO microstructures. The phage display technique was used to identify the 7-mer peptide SnBP01 (LPPWKLK), which shows a high binding affinity towards crystalline SnO. It was found that the derivatives of the SnBP01 peptide, varying in peptide length and thus in their interaction, significantly affect the aspect ratio and the size dimension of mineralized SnO particles, resulting in flower-like morphology. Furthermore, the important role of the N-terminal leucine residue in the peptide for the strong organic-inorganic interaction was revealed by FTIR investigations. This bioinspired approach shows a facile procedure for the detailed investigation of peptide-to-metal oxide interactions, as well as an easy method for the controlled synthesis of tin(II) oxide particles with different morphologies.
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    Development of artificial single and double reading domains to analyze chromatin modification patterns
    (2018) Mauser, Rebekka; Jeltsch, Albert (Prof. Dr.)
    The unstructured N-terminal tails of histone proteins carry many different post-translational modifications (PTMs), like methylation, acetylation or phosphorylation. These PTMs can alter the chromatin structure, influence the interaction of adjacent nucleosomes and serve as specific binding sites for histone interacting domains. Currently, the investigation of histone tail PTMs is mainly based on antibodies, however concerns about the specificity of these antibodies and reproducibility of data arouse. Therefore, it was one aim of this thesis to develop alternative approaches to histone tail PTM antibodies. Previous studies already showed that histone modification interacting domains (HiMIDs) can replace histone tail antibodies in a highly effective manner. As part of this work, the TAF3 PHD domain was established as new H3K4me3 specific HiMID. In peptide array binding and Far-western blot assays, the domain showed a specific interaction with H3K4me3 modifications. Also in ChIP like experiments (CIDOP: Chromatin Interacting Domain Precipitation) coupled to qPCR and next generation sequencing, the domain showed a similar performance as validated H3K4me3 antibodies. With the proposal of the histone code hypothesis the question was raised if combinations of histone modifications carry specific biological functions. However, so far, the experimental analysis of the co-occurrence of histone modification on the same nucleosome in a genome-wide manner is a challenging task. For this reason, the main aim of this work was to develop double reading domains in which two histone reading domains are fused together with a flexible linker to achieve simultaneously readout of dual histone tail modifications in a single CIDOP experiment. To validate the concept, the Dnmt3a PWWP domain and the MPP8 Chromo domain were fused together and their specific recognitions of H3K36me2/3 and H3K9me3 histone tail modifications were analyzed. Biochemical investigations like peptide arrays, Far-western blot and western blot experiments showed that both domains specifically interact with their targets and preferentially interact with double modified chromatin. Additionally, the preferred interaction with double modified chromatin could be further verified with binding pocket mutants and methyl-lysine analogues. The newly generated double domain was used in chromatin precipitation experiments to identify genome regions where both modifications are present. The genome-wide distribution of the H3K36me2/3-H3K9me3 showed that this combination of histone marks represents a novel bivalent chromatin state, which is associated with weakly transcribed genes and is enriched for binding sites of ZNF274 and SetDB1. Also in this work, mixed peptide arrays were introduced as new screening method for the efficient analysis of double reading domains. The naturally occurring double reading domain of the BPTF protein was used to demonstrate the capability of this new screening tool. BPTF contains a PHD domain, which binds to H3K4me3 and a Bromo domain, which interacts with acetyl groups of the H4 tail. Synergistic binding to both peptides was shown using the newly developed mixed peptide arrays. Additionally, in the course of this work mixed peptide arrays were used to optimize several of the designed double reading domains. Furthermore, some other double reading domains were generated in this work, like PWWP-ATRX, MPP8 Chromo domain-L-double Tudor and CBX7 Chromo domain-L-MPP8 Chromo domain and analyzed for specific dual readout. Also double reading domains with dual specificity for DNA methylation and histone marks were generated. The firstly used methyl-DNA binding domain of the MBD2 protein showed a strong binding, dominating the effect of the HiMIDs. Therefore, the weaker but still specific methyl-DNA binding domain of the MBD1 protein was used. First experiments with this new fusion constructs showed a simultaneously interaction with chromatin which is associated with DNA methylation and histone PTMs. In summary, the studies with double reading domains showed that with this novel method precipitation of double modified chromatin is possible and that the genome-wide investigation of newly studied bivalent chromatin states is feasible. Therefore, this novel approach makes it possible to analyze many different combinations of histone modifications, investigate their influence on chromatin and gain a deeper understanding of the biological role behind histone tail modification patterns.
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    Microbial biostabilization in fine sediments
    (2022) Gerbersdorf, Sabine Ulrike; Wieprecht, Silke (Prof. Dr.-Ing.)
    Microbial biostabilization has increasingly received attention over the last years due to its significance for the dynamics of fine sediments in fluvial and coastal systems with implications for ecology, economy and human-health. This habilitation thesis highlights the contributions of the applicant and her team to this multi-disciplinary research area and is based on eight core publications that are presented in seven chapters. First, the topic of biofilm and biostabilization is introduced and second, the materials and methods applied are presented before own research findings are discussed. To start with, the stabilization potential of heterotrophic bacterial assemblages has been emphasised as well as the adhesive properties of the protein moieties within the EPS (extracellular polymeric substances) that are more significant than previously thought. Furthermore, the engineering potential of estuarine prokaryotic and eukaryotic assemblages has been studied separately and combined to reveal the effective cooperation of mixed biofilm that resulted in highest substratum stabilization although the effects were not clearly synergistic (=more than additive). The significance of biostabilization could be evidenced as well for freshwaters where highest adhesive capacity and sediment stability occurred during spring. Microbial community composition differed accordingly to result in mechanically highly diverse biofilm. Moreover, the importance of two of the most influential abiotic conditions, light intensity and hydrodynamics, was shown for biofilm growth, species composition and functionality - here biostabilization. In order to test adhesive properties at the relevant mesoscale (mm-cm) but non-destructively and highly sensitive, MagPI (Magnetic Particle Induction) has been applied. The last chapter concerns technical aspects to further improve its performance while demonstrating the impact of material and geometry and the importance of both, magnetic field strength and field gradient for the physics of the MagPI approach.