Artificial metalloenzymes in catalysis

Obrecht, Lorenz

January 2015

This thesis describes the synthesis, characterisation and application of artificial metalloenzymes as catalysts. The focus was on two mutants of SCP-2L (SCP-2L A100C and SCP-2L V83C) both of which possess a hydrophobic tunnel in which apolar substrates can accumulate. The crystal structure of SCP-2L A100C was determined and discussed with a special emphasis on its hydrophobic tunnel. The SCP-2L mutants were covalently modified at their unique cysteine with two different N-ligands (phenanthroline or dipicolylamine based) or three different phosphine ligands (all based on triphenylphosphine) in order to increase their binding capabilities towards metals. The metal binding capabilities of these artificial proteins towards different transition metals was determined. Phenanthroline modified SCP-2L was found to be a promising scaffold for Pd(II)-, Cu(II)-, Ni(II)- and Co(II)-enzymes while dipicolylamine-modified SCP-2L was found to be a promising scaffold for Pd(II)-enzymes. The rhodium binding capacity of two additional phosphine modified protein scaffolds was also investigated. Promising scaffolds for Rh(I)- and Ir(I)-enzymes were identified. Rh-enzymes of the phosphine modified proteins were tested in the aqueous-organic biphasic hydroformylation of linear long chain 1-alkenes and compared to the Rh/TPPTS reference system. Some Rh-enzymes were found to be several orders of magnitude more active than the model system while yielding comparable selectivities. The reason for this remarkable reactivity increase could not be fully elucidated but several potential modes of action could be excluded. Cu-, Co-, and Ni-enzymes of N-ligand modified SCP-2L A100C were tested in the asymmetric Diels-Alder reaction between cyclopentadiene and trans-azachalcone. A promising 29% ee for the exo-product was found for the phenanthroline modified protein in the presence of nickel. Further improvement of these catalyst systems by chemical means (e.g. optimisation of ligand structure) and bio-molecular tools (e.g. optimisation of protein environment) can lead to even more active and (enantio)selective catalysts in the future.

572

Amine Transaminases in Biocatalytic Amine Synthesis

Land, Henrik

January 2016

The use of enzymes, nature´s own catalysts, both isolated or as whole cells to perform chemical transformations is called biocatalysis. As a complement to classical chemical catalysis, biocatalysis can be an environmentally friendly and more economical option in the production and synthesis of chemicals. Research on the application of amine transaminases in synthesis of chiral amines have exploded over the last two decades and interest from the industry is increasing. Amine transaminases are promising catalysts due to their ability to perform reductive amination of ketones with excellent enantioselectivity. For a process to be efficient, high substrate specificity of the applied enzyme is an important factor. A variant of Chromobacterium violaceum amine transaminase that was obtained through rational design has an increased specific activity toward (S)-1-phenylethylamine and a set of 4´-substituted acetophenones. This result makes this variant a promising catalyst for the asymmetric synthesis of similar amines. Amine transaminase catalyzed asymmetric synthesis of amines generally suffers from unfavorable equilibrium. Two methods that include spontaneous tautomerization and biocatalytic amidation for equilibrium displacement have therefore been developed. Efficient assays and screening methods are demanded for the discovery and development of novel amine transaminases. For this purpose, a sensitive fluorescence-based assay that holds promise as a high-throughput screening method was developed. One of the major obstacles for application of enzymes in industrial processes is the instability of the enzyme toward harsh conditions. The stability of Chromobacterium violaceum amine transaminase was investigated and improved using co-solvents and other additives. Co-lyophilization with surfactants was also applied to improve the performance of the same enzyme in organic solvents. / <p>QC 20161017</p>

Amine Transaminase

Biocatalysis

Transamination

Reductive Amination

Enzyme

Enzyme Engineering

Equilibrium Displacement

Screening

Enzyme Stability

Studies of Enzyme Mechanism Using Isotopic Probes

Chen, Cheau-Yun

08 1900

The isotope partitioning studies of the Ascaris suum NAD-malic enzyme reaction were examined with five transitory complexes including E:NAD, E:NAD:Mg, E:malate, E:Mg:malate, and E:NAD:malate. Three productive complexes, E:NAD, E:NAD:Mg, and E:Mg:malate, were obtained, suggesting a steady-state random mechanism. Data for trapping with E:14C-NAD indicate a rapid equilibrium addition of Mg2+ prior to the addition of malate. Trapping with 14C-malate could only be obtained from the E:Mg2+:14C-malate complex, while no trapping from E:14C-malate was obtained under feasible experimental conditions. Most likely, E:malate is non-productive, as has been suggested from the kinetic analysis. The experiment with E:NAD:malate could not be carried out due to the turnover of trace amounts of malate dehydrogenase in the pulse solution. The equations for the isotope partitioning studies varying two substrates in the chase solution in an ordered terreactant reaction were derived, allowing a determination of the relative rates of substrate dissociation to the catalytic reaction for each of the productive transitory complexes. NAD and malate are released from the central complex at an identical rate, equal to the catalytic rate.

isotope partitioning studies

enzyme mechanism

Ascaris suum

NAD-malic enzyme

Enzyme kinetics.

Isotope separation.

ELUCIDATING THE HMG-COA REDUCTASE REACTION MECHANISM USING PH-TRIGGERED TIME-RESOLVED X-RAY CRYSTALLOGRAPHY

Vatsal Purohit (11825150)

18 December 2021

<p>HMG-CoA reductase from Pseudomonas mevalonii (<i>Pm</i>HMGR) catalyzes the oxidation of mevalonate and mevaldyl-CoA to form HMG-CoA using CoA-SH and two NAD+ cofactors. While the enzyme has been used extensively as a drug target in humans to treat hypercholesterolemia, its pathway has also been found to be critical for the survival of antibiotic resistant gram-positive bacteria. Structural studies using non-productive and slow-substrate binary complexes as well as biochemical studies using half and full reactions led to the proposal that the conversion of mevalonate to HMG-CoA occurs through the generation of two intermediates, mevaldehyde and mevaldyl-CoA (Shown in Fig 1.1). However, several intermediary changes along the <i>Pm</i>HMGR reaction pathway remain unclear. By gathering information about the enzyme’s intermediate states via structural studies, we could identify potential allosteric sites that further the reaction mechanism. Using this knowledge, we could design enzyme inhibitors that act as novel antibacterials. The application of time-resolved crystallographic methods would provide structural information about transitory states in the PmHMGR reaction mechanism. The <i>Pm</i>HMGR crystal has been shown to be suitable for time-resolved crystallographic measurements for the reaction steps resulting in mevaldyl-CoA formation. However, our structural investigations of the mevalonate, CoA and NAD+ complex that are expected to result in the formation of mevaldehyde (Fig 1.1) do not show any changes corresponding to a turnover in the crystal environment. <br></p><p><br></p><p>To investigate the factors limiting enzymatic activity in the crystal, we investigated the effects of pH and specific ions in the crystallization environment. Kinetic studies indicated a strong <i>Pm</i>HMHGR inhibition in the crystallization buffer that is dependent on the concentration of the crystallization precipitant ammonium sulfate. These studies also indicated an increase in enzyme turnover with increasing pH. Utilizing the ionic concentration and pH-dependent properties of the enzyme in the crystallization environment, we have developed a reaction triggering approach using pH changes for <i>Pm</i>HMGR crystals.<br></p><p><br></p><p>We have demonstrated our application of this ‘pH-jump’ method by observing changes in <i>Pm</i>HMGR crystals after reaction initiation. Changes in the density of mevalonate, CoA and NAD+have indicated mevaldehyde and mevaldyl-CoA formation. Additionally, the appearance of a unique NADH absorbance peak after the pH-change has also highlighted the initiation of the <i>Pm</i>HMGR reaction and the occurrence of a hydride transfer step. Our analysis of the movements using time-resolved structures post reaction-initiation have also highlighted structural changes and inter-domain contacts in the small and flap domain that would allow cofactor exchange and product release. The pH-jump method can hence be utilized as a novel approach for triggering the <i>Pm</i>HMGR reaction in crystals and further studying transitory states along its reaction pathway.<br></p>

Biophysics

Structural Biology

Enzymes

Time-resolved crystallography

enzyme biochemistry

enzyme dynamics

Enzyme Kinetics

crystallography

The role of interfacial and 'entropic' enzymes in transitory starch degradation : a mathematical modeling approach

Kartal, Önder

January 2011

Plants and some unicellular algae store carbon in the form of transitory starch on a diurnal basis. The turnover of this glucose polymer is tightly regulated and timely synthesis as well as mobilization is essential to provide energy for heterotrophic growth. Especially for starch degradation, novel enzymes and mechanisms have been proposed recently. However, the catalytic properties of these enzymes and their coordination with metabolic regulation are still to be discovered. This thesis develops theoretical methods in order to interpret and analyze enzymes and their role in starch degradation. In the first part, a novel description of interfacial enzyme catalysis is proposed. Since the initial steps of starch degradation involve reactions at the starch-stroma interface it is necessary to have a framework which allows the derivation of interfacial enzyme rate laws. A cornerstone of the method is the introduction of the available area function - a concept from surface physics - to describe the adsorption step in the catalytic cycle. The method is applied to derive rate laws for two hydrolases, the Beta-amylase (BAM3) and the Isoamylase (DBE/ISA3), as well as to the Glucan, water dikinase (GWD) and a Phosphoglucan phosphatase (DSP/SEX4). The second part uses the interfacial rate laws to formulate a kinetic model of starch degradation. It aims at reproducing the stimulatory effect of reversible phosphorylation by GWD and DSP on the breakdown of the granule. The model can describe the dynamics of interfacial properties during degradation and suggests that interfacial amylopectin side-chains undergo spontaneous helix-coil transitions. Reversible phosphorylation has a synergistic effect on glucan release especially in the early phase dropping off during degradation. Based on the model, the hypothesis is formulated that interfacial phosphorylation is important for the rapid switch from starch synthesis to starch degradation. The third part takes a broader perspective on carbohydrate-active enzymes (CAZymes) but is motivated by the organization of the downstream pathway of starch breakdown. This comprises Alpha-1,4-glucanotransferases (DPE1 and DPE2) and Alpha-glucan-phosphorylases (Pho or PHS) both in the stroma and in the cytosol. CAZymes accept many different substrates and catalyze numerous reactions and therefore cannot be characterized in classical enzymological terms. A concise characterization is provided by conceptually linking statistical thermodynamics and polymer biochemistry. Each reactant is interpreted as an energy level, transitions between which are constrained by the enzymatic mechanisms. Combinations of in vitro assays of polymer-active CAZymes essential for carbon metabolism in plants confirmed the dominance of entropic gradients. The principle of entropy maximization provides a generalization of the equilibrium constant. Stochastic simulations confirm the results and suggest that randomization of metabolites in the cytosolic pool of soluble heteroglycans (SHG) may contribute to a robust integration of fluctuating carbon fluxes coming from chloroplasts. / Stärke hat eine herausragende Bedeutung für die menschliche Ernährung. Sie ist ein komplexes, wasserunlösliches Glucosepolymer und dient - als eine der wichtigsten Speicherformen von Kohlenhydraten in Pflanzen - der Aufrechterhaltung des Energiestoffwechsels. Unterschiedliche Organe enthalten Stärke. In Knollen und Samen wird die sogenannte Speicherstärke über lange Zeiträume auf- und abgebaut. Die im Allgemeinen weniger bekannte transitorische Stärke in Blättern und einigen einzelligen Algen wird in einem täglichen Rhythmus umgesetzt: Sie wird während der Photosynthese aufgebaut und in der Nacht abgebaut. Experimentelle Studien haben nachgewiesen, dass die Fähigkeit der Pflanze, den Abbau transitorischer Stärke zu regeln, essentiell ist, um während der Nacht das Wachstum der Pflanze zu gewährleisten. Da die Geschwindigkeit von biochemischen Reaktionen über Enzyme reguliert wird, ist die Aufklärung ihrer Funktion im Stoffwechsel eine notwendige Voraussetzung, um den komplexen Prozess des Wachstums zu erklären. Die vorliegende Arbeit stellt einen Versuch dar, die Funktion von Enzymen beim Stärkeabbau anhand von mathematischen Modellen und Computersimulationen besser zu verstehen. Dieser Ansatz erlaubt es, Eigenschaften des Systems durch Abstraktion anhand eines idealisierten Abbildes herzuleiten. Die mathematisch notwendigen Folgerungen dienen der Aufstellung von Hypothesen, die wiederum mit experimentellen Resultaten konfrontiert werden können. Stoffwechselsysteme sind komplexe Untersuchungsobjekte, bei denen eine rein qualitative Argumentation schnell an Grenzen gerät, wo mathematische Methoden die Möglichkeit von Aussagen noch zulassen. Der erste Teil der Arbeit entwickelt einen theoretischen Rahmen, um Gleichungen für die Geschwindigkeit oberflächenaktiver Enzyme herzuleiten. Dies ist notwendig, da die ersten Reaktionen, die dem Stärkeabbau zugeordnet werden, an ihrer Oberfläche stattfinden. Die Methode wird auf vier essentielle Enzyme angewandt: zwei abbauende Enzyme (Beta-Amylase und Isoamylase) und zwei den Abbau unterstützende Enzyme (Alpha-Glucan,Wasser-Dikinase und Phosphoglucan Phosphatase). Der zweite Teil entwickelt ein kinetisches Modell des Stärkeabbaus unter Verwendung der hergeleiteten Ratengleichungen. Das Modell bildet die Dynamik des Systems realistisch ab und legt nahe, dass ein spontaner Phasenübergang an der Oberfläche von geordneten zu weniger geordneten Zuständen stattfindet. Ferner wird die Hypothese aufgestellt, dass die reversible Modifikation der Oberfläche durch Enzyme besonders in der Anfangsphase des Abbaus einen synergetischen Effekt hat, d.h. den Abbau enorm beschleunigt. Dies könnte beim schnellen Umschalten von Stärkeaufbau zu Stärkeabbau regulatorisch relevant sein. Im letzten Teil werden kohlenhydrataktive Enzyme betrachtet, die in der löslichen Phase die Produkte des Stärkeabbaus weiterverarbeiten. Da diese sogenannten Transferasen auch in vielen anderen Organismen und Stoffwechselwegen vorkommen, wird ein allgemeiner Standpunkt eingenommen. Anhand von Methoden aus der statistischen Physik wird theoretisch wie experimentell nachgewiesen, dass diese Enzyme spontan die Entropie innerhalb des Stoffwechselsystems erhöhen. Diese Neigung, "Unordnung" zu schaffen, wird vom Organismus aber paradoxerweise ausgenutzt, um die Weiterverarbeitung von Kohlenhydraten im Stärkestoffwechsel zu stabilisieren. Dieser Mechanismus eröffnet einen neuen Blick auf energie- und entropiegetriebene Prozesse in Zellen.

Enzymkinetik

Enzymadsorption

Disproportionierungsenzym

Polysaccharide

Statistische Physik

Enzyme kinetics

Enzyme adsorption

Disproportionating Enzyme

Polysaccharides

Statistical Physics

Life sciences

Characterization of CYP2C9 residues important for conferring substrate specificity and inter-individual variability in drug metabolism /

Dickmann, Leslie J.

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 99-107).

Building blocks for polymer synthesis by enzymatic catalysis

Semlitsch, Stefan

January 2017

The search for alternatives to oil-based monomers has sparked interest for scientists to focus on the use of renewable resources for energy production, for the synthesis of polymeric materials and in other areas. With the use of renewable resources, scientists face new challenges to first isolate interesting molecules and then to process them. Enzymes are nature’s own powerful catalysts and display a variety of activities. They regulate important functions in life. They can also be used for chemical synthesis due to their efficiency, selectivity and mild reaction conditions. The selectivity of the enzyme allows specific reactions enabling the design of building blocks for polymers. In the work presented here, a lipase (Candida antarctica lipase B (CalB)) was used to produce building blocks for polymers. An efficient route was developed to selectively process epoxy-functional fatty acids into resins with a variety of functional groups (maleimide, oxetane, thiol, methacrylate). These oligoester structures, based on epoxy fatty acids from birch bark and vegetable oils, could be selectively cured to form thermosets with tailored properties. The specificity of an esterase with acyl transfer activity from Mycobacterium smegmatis (MsAcT) was altered by rational design. The produced variants increased the substrate scope and were then used to synthesize amides in water, where the wild type showed no conversion. A synthetic procedure was developed to form mixed dicarboxylic esters by selectively reacting only one side of divinyl adipate in order to introduce additional functional groups. / <p>QC 20170823</p>

Enzyme

Enzyme Engineering

Biocatalysis

Lipase

CalB

MsAcT

Substrate specificity

Selectivity

Polymer Chemistry

Polymer Synthesis

Biocatalysis and Enzyme Technology

Biokatalys och enzymteknik

Organic Phase Entrapment of Glucose Oxidase In Polymeric Nanoparticles

Hancock, James

12 May 2008

No description available.

Biochemistry

Chemical Engineering

Engineering

Particle Physics

Polymers

nanoparticle

nanotechnology

enzyme immobilization

enzyme entrapment

enzyme kinetics

polymer swelling

The inactivation and removal of proteolytic enzymes from amylolytic supplements

Dirks, Brinton Marlo.

January 1948

LD2668 .T4 1948 D5 / Master of Science

Proteolytic enzymes

Enzyme inhibitors.

Masters theses

Physiological and genetic studies with trypsin inhibitor of corn (Zea mays L.)

Morris, Sizi Zubahyea.

January 1978

Call number: LD2668 .T4 1978 M68 / Master of Science

Enzyme inhibitors.

Trypsin.

Corn--Composition.

Masters theses