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151	Engineering of novel Biocatalysts with Functionalities beyond Nature Gespers (Akal), Anastassja 01 1900 (has links) Novel biocatalysts are highly demanded in the white biotechnology. Hence, the development of highly stable and enantioselective biocatalysts with novel functionalities is an ongoing research topic. Here, an osmium ligating single-site ArM was created based on the biotinstreptavidin technology for the dihydroxylation of olefins. For the creation of the artificial catalytic metal center in the streptavidin (SAV) cavity, efficient osmium tetroxide (OsO4) chelating biotin-ligands were created. The unspecific metal binding of the host scaffold was diminished through genetical and chemical modification of the host protein. The created single-site OsO4 chelating ArM was successfully applied in the asymmetric cyclopropanation, revealing a stable and tunable catalytic hybrid system for application. The structural analysis of protein-ligand complexes is essential for the advanced rational design and engineering of artificial metalloenzymes. In previous studies, a SAV-dirhodium ArM was created and successfully applied in the asymmetric cyclopropanation reaction. To improve the selectivity of the SAV-dirhodium complex, the structural location of the organometallic complex in the SAV cavity was targeted and small-angle x-ray scattering (SAXS) was used to obtain the structural information. The SAXS analysis revealed valuable information of the molecular state of the complexes; hence, the method proved to be useful for the structural analysis of protein-ligand interactions. The discovery of novel enzymes from nature is still the major source for improved biocatalysts. One of the most important enzymes used in the molecular biology are DNA polymerases in PCR reactions. The halothermophilic brine-pool 3 polymerase (BR3 Pol) from the Atlantis II Red Sea brine pool showed optimal activities at 55 °C and salt concentrations up to 0.5 M NaCl, and was stable at temperatures above 95 °C. The comparison with the hyperthermophilic KOD polymerase revealed the haloadaptation of BR3 Pol due to an increased negative electrostatic surface charge and an overall higher structural flexibility. Engineered chimeric KOD polymerases with swapped single BR3 Pol domains revealed increased salt tolerance in the PCR, showing increased structural flexibility and a local negative surface charge. The understanding of the BR3 Pol haloadaptation might enable the development of a DNA polymerase tailored for specific PCR reactions with increased salt concentrations. Biocatalysis DNA polymerase Artificial Metalloensymes protein engineering Halo-thermophilic Streptavidin-Biotin
152	Effect of Protein Charge and Charge Distribution on Protein-Based Complex Coacervates Kapelner, Rachel A. January 2021 (has links) Polyelectrolytes of opposite charge in aqueous solution can undergo a liquid-liquid phase separation known as complex coacervation. Complex coacervation of ampholytic proteins with oppositely charged polyelectrolytes is of increasing interest as it results in a protein rich phase that has potential applications in food science, protein therapeutics, protein purification, and biocatalysis. However, many globular proteins do not phase separate when mixed with an oppositely charged polyelectrolyte, and those that do phase separate do so over narrow concentration, pH, and ionic strength ranges. Much of the work that has been done on complex coacervates looks at polymer-polymer systems. While there have been some initial studies showing that proteins can undergo complex coacervation, the major design factor studied to date has been overall protein charge. The tools of genetic engineering, which allow the precise tuning and placement of charge have not been used to more fully understand the design criteria for protein complex coacervation. In this dissertation, we developed a model protein library based on green fluorescent protein (GFP) to study the impact of protein net charge and charge distribution on protein phase separation with polyelectrolytes. We developed a short, ionic polypeptide sequence (6-18 amino acids) that can drive the liquid-liquid phase separation of globular proteins. We characterize the phase behavior of the protein library with a homopolymer and diblock copolymer of similar chemistry to elucidate how protein design impacts macro- and microphase separation. In these phase characterization studies, differences in the nature of phase separation as well as the salt stability of the protein coacervates with the different polymer species are identified. We finally used this model protein library to study the effects of the protein design and phase separation behavior for coacervate-based applications including intracellular protein delivery, purification, and protein stabilization. Chemical engineering Coacervation Polyelectrolytes Electrolyte solutions Water chemistry Ampholytes Proteins--Therapeutic use Biocatalysis
153	Untersuchungen zu stereoselektiven Reduktionen ausgewählter α-substituierter β-Ketocarbonsäureester durch bio- und chemokatalytische Transformationen Trapp, Christian 09 August 2021 (has links) Gegenstand der vorliegenden Arbeit war die Synthese von enantiomerenreinen α-substituierten β-Hydroxyestern zu neuartigen 4,5-disubstituieren Oxazolidin-2-onen, die auch als EVANS-Auxilare bekannt sind. Chemokatalyse, Biokatalyse, Hydroxyester info:eu-repo/classification/ddc/540 ddc:540
154	Whole-cell redox biocatalysis driven by photosynthesis – an integrated bioprocess design for phototrophic biocatalysts Hoschek, Anna 24 July 2019 (has links) Much success was already achieved for the development of efficient oxyfunctionalization bioprocesses by the application of oxygenases in heterotrophic whole-cell host systems. However, several restrictions such as the technically limited O2 supply and carbohydrate-based electron supply still limit their implementation on an industrial scale concerning production rates and costs. The use of phototrophic organisms as whole-cell biocatalysts for oxygenase-based biotransformations provides an alternative and promising technology for the eco-efficient production of oxyfunctionalized value-added chemicals. While numerous cyanobacterial or microalgal bioprocesses were already developed for CO2-derived fermentations, biotransformation processes relying on the generation of activated reduction equivalents as well as O2-derived from photosynthetic water oxidation are rare. In this context, research mainly focuses on the demonstration of engineered catalysts with emphasis on the production of hydrogen. Yet, an integrated bioprocess design for the application of phototrophic organisms in redox biotransformations beyond the proof-of-concept catalyst development is lacking. This thesis aims at the integrated application of biotechnological methods and strategies for the development of eco-efficient photosynthesis-driven oxyfunctionalization processes. The main research question combines the conceptual evaluation of photosynthetic electron and O2 supply with the technical applicability of cyanobacteria as phototrophic host organisms in a hydrocarbon oxyfunctionalization bioprocess. Using a guide of integrated bioprocess design, biocatalyst, reaction, and process engineering tools are applied for the establishment of new, photosynthesis-driven bioprocesses. info:eu-repo/classification/ddc/570 ddc:570
155	Exploring the potential of transaminases in aqueous organic solvent solutions through protein engineering: a resource to optimise the synthesis of chiral amines Fasol, Silvia January 2014 (has links) No description available. biocatalysis protein engineering enzymology aminotransferase biochemistry industrial biotechnology protein stability Engineering and Technology Teknik och teknologier
156	Emergent Properties of Biomolecular Organization Tsitkov, Stanislav January 2021 (has links) The organization of molecules within a cell is central to cellular processes ranging from metabolism and damage repair to migration and replication. Uncovering the emergent properties of this biomolecular organization can improve our understanding of how organisms function and reveal ways to repurpose their components outside of the cell. This dissertation focuses on the role of organization in two widely studied systems: enzyme cascades and active cytoskeletal filaments.Part I of this dissertation studies the emergent properties of the spatial organization of enzyme cascades. Enzyme cascades consist of a series of enzymes that catalyze sequential reactions: the product of one enzyme is the substrate of a subsequent enzyme. Enzyme cascades are a fundamental component of cellular reaction pathways, and spatial organization of the cascading enzymes is often essential to their function. For example, cascading enzymes assembled into multi-enzyme complexes can protect unstable cascade intermediates from the environment by forming tunnels between active sites. We use mathematical modeling to investigate the role of spatial organization in three specific systems. First, we examine enzyme cascade reactions occurring in multi-enzyme complexes where active sites are connected by tunnels. Using stochastic simulations and theoretical results from queueing theory, we demonstrate that the fluctuations arising from the small number of molecules involved can cause non-negligible disruptions to cascade throughput. Second, we develop a set of design principles for a compartmentalized cascade reaction with an unstable intermediate and show that there exists a critical kinetics-dependent threshold at which compartments become useful. Third, we investigate enzyme cascades immobilized on a synthetic DNA origami scaffold and show that the scaffold can create a favorable microenvironment for catalysis. Part II of this dissertation focuses on the organization of active cytoskeletal filaments. Many mechanical processes of a cell, such as cell division, cell migration, and intracellular transport, are driven by the ATP-fueled motion of motor proteins (kinesin, dynein, or myosin) along cytoskeletal filaments (microtubules or actin filaments). Over the past two decades, researchers have been repurposing motor protein-driven propulsion outside of the cell to create systems where cytoskeletal filaments glide on surfaces coated with motor proteins. The study of these systems not only elucidates the mechanisms of force production within the cell, but also opens new avenues for applications ranging from molecular detection to computation. We examine how microtubules gliding on surfaces coated with kinesin motor proteins can generate collective behavior in response to mutualistic interactions between the filaments and motors, thereby maximizing the utilization of system components and production. To this end, we used a microtubule-kinesin system where motors reversibly bind to the surface. In experiments, microtubules gliding on these reversibly bound motors were unable to cross each other and at high enough densities began to align and form long, dense bundles. The kinesin motors accumulated in trails surrounding the microtubule bundles and participated in microtubule transport. In conclusion, our study of the emergent properties of the spatial organization of enzyme cascades and the mutualistic interactions within active systems of motor proteins and cytoskeletal filaments provides insight into both how these systems function within cells and how they can be repurposed outside of them. Biomedical engineering Biocatalysis Catalysis Microtubules Cytoskeletal proteins Kinesin Molecular biology--Mathematical models Stochastic analysis
157	Enhancing Protein and Enzyme Stability Through Rationally Engineered Site-Specific Immobilization Utilizing Non-Canonical Amino Acids Wu, Jeffrey Chun 01 December 2014 (has links) (PDF) The demand for economical, efficient protein production, reuse, and recovery has never been greater due to their versatility in a large variety of applications ranging from industrial chemical manufacturing to pharmaceutical drug production. The applications for naturally and artificially produced proteins include protein drugs and other pharmaceutical products, as biocatalysts in environmentally friendly chemical manufacturing, as enzymes for food processing purposes, and as an essential component in many biomedical devices. However, protein production suffers from many challenges, which include the cost of production, protein stability especially under harsh conditions, and recoverability and reusability of the proteins. The combination of two developing technologies, cell-free protein synthesis systems (CFPS) and unnatural amino acid incorporation, provides solutions to these protein production challenges.This dissertation reports on the use of cell-free protein synthesis systems and unnatural amino acid incorporation to develop new proteins and enzyme immobilization techniques that significantly increase activity and stability while simplifying recoverability and reuse. Synthetic biology biocatalysis enzyme immobilization cell-free synthetic biology green manufacturing protein immobilization click chemistry Microbiology
158	Enzymatic cascade for dynamic kinetic resolution of amines Listén Hedlin, Embla January 2017 (has links) No description available. Biocatalysis Chiral amines Assymmetric synthesis Transaminases Enzymatic racemisation Engineering and Technology Teknik och teknologier
159	Development of a Thioredoxin-Based Cofactor Regeneration System for NADPH-Dependent Oxidoreductases Zhang, Ningning, Müller, Beatrice, Ørtoft Kirkeby, Tanja, Kara, Selin, Loderer, Christoph 02 February 2024 (has links) Nicotinamide cofactor-dependent oxidoreductases have become a valuable tool for the synthesis of high value chiral compounds. The feasibility of biocatalytic processes involving these enzymes stands and falls with the efficiency of the regeneration of cofactors. In this study, we describe a novel NADPH regeneration method based on the natural thioredoxin electron delivery system. Thioredoxin 1 (Trx1) and thioredoxin reductase (TR) from Thermus thermophilus were characterized for the dithiol-dependent reduction of NADP+, revealing good catalytic activities and a particularly remarkable thermostability. The TR/Trx1 system was then coupled with two representative NADPH-dependent oxidoreductases, alcohol dehydrogenase and cyclohexanone monooxygenase. Reaction conditions for both systems were optimized for reaction yield and selectivity. The results demonstrate the feasibility of the TR/Trx1-system for its application as NADPH regeneration system. info:eu-repo/classification/ddc/540 ddc:540
160	Development of Novel Mesoporous Silicates for Bioseparations and Biocatalysis KATIYAR, AMIT 18 April 2008 (has links) No description available. BioseparationS Biocatalysis Mesoporous Silica Spherical SBA-15 Particles Calorimtery of Protein Adsorption

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