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Abstract
Biocatalysis has found numerous applications in various fields as an alternative to chemical catalysis. The use of enzymes in organic synthesis, especially to make chiral compounds for pharmaceuticals as well for the flavors and fragrance industry, are the most prominent examples. In addition, biocatalysts are used on a large scale to make specialty and even bulk chemicals. This review intends to give illustrative examples in this field with a special focus on scalable chemical production using enzymes. It also discusses the opportunities and limitations of enzymatic syntheses using distinct examples and provides an outlook on emerging enzyme classes.
The definition of Green Chemistry was first formulated at the beginning of the 1990s – 30 years ago and states as follows: “design of chemical products and processes to reduce or eliminate the use and generation of hazardous substances” (Poliakoff et al. 2002). Biocatalysis is one of the examples of “green” chemistry as it is relying on natural or modified enzymes. Today, biocatalysis is a standard technology for the production of chemicals (Straathof et al. 2002).
In this PhD thesis, the implications of biocatalysis using different class of enzymes are discussed: two cytochrome P450 monoxygenases, two kinases and one lyase are shown as tools for the production of bioactive compounds.
The P450 enzymes have a central role in the oxidative metabolism of a wide variety of compounds including the synthesis of endogenous substrates such as steroids and fatty acids. Moreover, P450s catalyze the hydroxylation of non-activated carbon atoms in a regio- and stereospecific fashion avoiding use of protecting groups and several, time-consuming chemical steps.
Here, the recombinant expression and biocatalytic characterization of bacterial CYP107D1 for the regio- and stereoselective hydroxylation of two steroid compounds is reported. Since the natural electron transfer partners of these P450s are unknown, PdX and PdR from P. putida were employed to supply CYP107D1 with the necessary electrons for catalysis. This three-component system was used in bioconversions of two bile acids: LCA and DCA. P450 CYP107D1 exhibits high regio- and stereoselectivity for the tested steroids, giving 6β-hydroxylated products. The properties of the CYP107D1 make this multifaceted P450 monooxygenase an attractive enzyme for the production of novel drug metabolites. Moreover, the crystal structure of the enzyme is known, which provides the basis for developing a protein-engineering strategy aimed at catalytic properties of the CYP107D1
The second enzyme described in the thesis is the self-sufficient cytochrome P450 monooxygenase from Fusarium graminarium (FG067). From the overall structure, it resembles the well investigated CYP102 from Bacillus megaterium (CYP BM3) and the P450 from Fusarium oxysporum (CYPfoxy). In this study, two different strategies to recombinantly produce the fungal P450 monooxygenase P450-FG067, namely (a) producing in E. coli and (b) producing in P. pastoris were investigated. The P450 FG_067 from Fusarium graminarium was successfully overexpressed in P. pastoris. The enzyme was functionally active, converted fatty acid substrates of carbon chain length C10-16 with regiospecificity of the hydroxylating position ω -1, ω - 2 and ω-3, with the highest affinity for capric acid. The hydroxylation at different positions of the fatty acid chain is needed for different chemical industries. For example, ω-HFAs can be used as starting materials for the synthesis of polymers, with high resistance to heat or chemicals (Xiao et al. 2018). Therefore, the application of recombinant enzyme such as self-sufficient P450 FG_067 for a commercial production of HFAs is in high industrial demand.
In this thesis, two kinases were used for the producton of phosphorylated metabolites. Kinases catalyzing N-phosphorylation, which are of synthetic interest because of tedious chemical procedures in selective chemical N-phosphorylations. A highly active and stabile arginine kinase, obtained by cloning and expressing the argK gene from Limulus polyphemus in E. coli, was used in the one-step synthesis of Nω-phospho-L-arginine using the phosphoenolpyruvate/pyruvate kinase system for ATP regeneration. Applying arginine kinase in biocatalysis opens up new opportunities for the selective biocatalytic N-phosphorylation of interesting low-molecular-weight compounds and metabolites.
Another kinase investigated in this thesis was shikimate kinase. The highly active and stable shikimate kinase AroL was achieved by synthesizing the codon-optimized aroL gene and expressing it in high yield in E. coli. Next, shikimate kinase was used in an one-step synthesis of shikimate-3-phosphate using the phosphoenolpyruvate/pyruvate kinase system for ATP regeneration. Development of the described biocatalytic preparation of shikimate-3-phosphate is a superior route incomparison to a tedious multi-step and low yield classical synthesis of this compound. The biocatalytic phosphorylation is of great interest for a commercial production of metabolites and metabolite-like structures.
The last investigeted enzyme in this PhD thesis was argininosuccinate lyase from Saccharomyces cerevisiae. The argininosuccinate lyase was cloned and overexpressed in E. coli as a highly active and stable biocatalyst. A simple and straightforward biocatalytic asymmetric Michael addition reaction has been established for the synthesis of the key metabolite N-(([(4S)-4-amino-4-carboxybutyl]amino)imino methyl)-L-aspartic acid, commonly referred to as L-argininosuccinate. This one-step addition reaction was developed by running part of the urea cycle in reverse. The use of this argininosuccinate lyase and reaction monitoring by NMR enabled the development of a biocatalytic asymmetric Michael addition reaction as a novel green chemistry route with high molecular economy for the synthesis of this important metabolite at gram scale.
Recent advances in the field of scientific research have helped to understand the structure and functional activities of enzymes, which has in turn led to an increase in their stability, activity and substrate specificity. Nowadays, biocatalysis provide more sustainable, efficient, and less polluting methods for the production of fine chemicals and advanced pharmaceutical intermediates. The biocatalysts used in this thesis are introduced as a technology for the efficient synthesis of biologically active compounds, which is greener, reduces pollution and costs compared to chemical synthesis. In summary, the pharmaceutical industry should use the advantage of the progress of biochemistry to obtain biocatalysts in the production of fine chemicals on an industrial scale, improving the quality of end products and saving costs.
In 2010, the identification of 17 novel (R)-ATAs represented a breakthrough for the biocatalytic asymmetric synthesis of chiral amines, because only one (R)-ATA was described before. These novel ATAs were identified in a bioinformatic approach by studying the substrate acceptance of BCATs and DATAs to deduce the unknown substrate coordination of (R)-ATAs. Article I describes an alternative approach for the identification of (R)-ATA activity by reengineering the substrate- recognition site of α-AATs. While the engineering of the eBCAT led to the formation of an initial (R)-amine acceptance only, the (R)-ATA activity was successfully introduced in the DATA scaffold. These results demonstrate the transformation of an α-AAT in a moderately active (R)-ATA for the first time and highlight the evolutionary relationship between α-AATs and ATAs. Despite the availability of different ATAs nowadays, their substrate spectrum is limited due to the natural composition of their active sites. Several protein-engineering studies showed the widening of the substrate spectrum and the acceptance of bulky substrates by screening large mutant libraries to identify beneficial variants. In Article II, we developed an in silico engineering approach for amine transaminases to improve the conversion of bulky substrates and to reduce the number of variants to be tested in the laboratory. The resulting double-mutants of the (S)-ATA from C. violaceum displayed a >200-fold improved activity towards the bulky benchmark substrate. These variants expand the available biocatalytic toolbox for the synthesis of bulky amines, and the developed framework paves the way for rational protein-engineering protocols.
By studying unconventional transaminase substrates, we explored the potential of the available in- house transaminase toolbox in Articles III, IV, V, and VI. In Article III, we showed the transamination of a β-keto ester, leading to the synthesis of β-phenylalanine. The described cascade in Article IV enables the synthesis of amino carbohydrates. In addition, Article V describes an enzymatic cascade for the synthesis of amino fatty acids, which was extended in Article VI to obtain fatty amines.
The findings of this thesis clearly contribute to the understanding of the substrate scope and specificity of amine transaminases and expand the application of this versatile biocatalyst beyond classical ketone substrates.
Inflammatory Joint Disease Is a Risk Factor for Streptococcal Sepsis and Septic Arthritis in Mice
(2020)
Septic arthritis is a medical emergency associated with high morbidity and mortality, yet hardly any novel advances exist for its clinical management. Despite septic arthritis being a global health burden, experimental data uncovering its etiopathogenesis remain scarce. In particular, any interplay between septic arthritis and preceding joint diseases are unknown as is the contribution of the synovial membrane to the onset of inflammation. Using C57BL/6 mice as a model to study sepsis, we discovered that Group A Streptococcus (GAS) – an important pathogen causing septic arthritis - was able to invade the articular microenvironment. Bacterial invasion resulted in the infiltration of immune cells and detrimental inflammation. In vitro infected fibroblast-like synoviocytes induced the expression of chemokines (Ccl2, Cxcl2), inflammatory cytokines (Tnf, Il6), and integrin ligands (ICAM-1, VCAM-1). Apart from orchestrating immune cell attraction and retention, synoviocytes also upregulated mediators impacting on bone remodeling (Rankl) and cartilage integrity (Mmp13). Using collagen-induced arthritis in DBA/1 × B10.Q F1 mice, we could show that an inflammatory joint disease exacerbated subsequent septic arthritis which was associated with an excessive release of cytokines and eicosanoids. Importantly, the severity of joint inflammation controlled the extent of bone erosions during septic arthritis. In order to ameliorate septic arthritis, our results suggest that targeting synoviocytes might be a promising approach when treating patients with inflammatory joint disease for sepsis.
This thesis deals with the process considerations and optimizations of a whole-cell enzyme cascade reaction for the synthesis of ɛ-caprolactone. The enzyme cascade synthesis of ɛ-caprolactone has been conceptualized and verified using a dehydrogenase and a monooxygenase. The advantage of this enzyme combination is the closed-loop co-factor regeneration. Dehydrogenase and monooxygenase expressed in discrete whole cells were applied in defined ratio to conceptualize the cascade reaction. This necessitates the use of separate co-factor regeneration system due to impermeability of the E. coli cell wall to the co-factor. Article I deal with the design and optimization of dehydrogenase and monooxygenase co-expression in a same E. coli cell. In Article II, the cascade reaction was upscaled and a fed-batch process was realized. Following which, the important reaction metrices were analyzed and optimized. Article III extends the two-enzyme cascade with a lipase. The use of lipase helps to overcome the product inhibition of monooxygenase by ɛ-caprolactone.
Abstract
Methylation of free hydroxyl groups is an important modification for flavonoids. It not only greatly increases absorption and oral bioavailability of flavonoids, but also brings new biological activities. Flavonoid methylation is usually achieved by a specific group of plant O‐methyltransferases (OMTs) which typically exhibit high substrate specificity. Here we investigated the effect of several residues in the binding pocket of the Clarkia breweri isoeugenol OMT on the substrate scope and regioselectivity against flavonoids. The mutation T133M, identified as reported in our previous publication, increased the activity of the enzyme against several flavonoids, namely eriodictyol, naringenin, luteolin, quercetin and even the isoflavonoid genistein, while a reduced set of amino acids at positions 322 and 326 affected both, the activity and the regioselectivity of the methyltranferase. On the basis of this work, methylated flavonoids that are rare in nature were produced in high purity.
The aim of our research is a stereoselective synthesis development of 4-aminocyclohexanol by the application of a keto reductase (KRED) and an amine transaminase (ATA). 4-Aminocyclohexanol is a valuable precursor for active pharmaceutical ingredients, for example, lomibuvir (a HCV protease inhibitor), ambroxol (a secretolytic agent) and other bioactive molecules. Today, the trans-4-aminocyclohexanol is accessed via Ni-catalyzed synthetic procedure giving moderate yields. In our project we perform cis- and trans-4-aminocyclohexanol synthesis from 1,4-cyclohexanedione (a bio-based precursor) by an one-pot approach combining sequentially a KRED and an ATA as catalysts. For this, we envisaged two multistep enzymatic procedures. The route A would involve 4-hydroxycyclohexanone formation from 1,4-cyclohexanedione via a KRED-catalyzed monoreduction and a further transamination mediated by an ATA towards 4-aminocyclohexanol. The route B would consist of switching the steps of the previous sequential approach, that is, a monoamination of the diketone to yield 4-aminocyclohexanone, and the subsequent reduction of the remaining carbonyl group. Only route A turned out to be feasible, and we performed 4-aminocyclohexanol synthesis at the preparative scale in the sequential and tandem modes. Depending on the ATA, both isomers can be obtained.
Disregarded Measurement Uncertainty Contributions and Their Magnitude in Measuring Plasma Glucose
(2020)
Background:
Each measurement is subject to measurement uncertainty (MU). Consequently, each measurement of plasma glucose concentration used for diagnosis and monitoring of diabetes mellitus (DM) is affected. Although concepts and methods of MU are well established in many fields of science and technology, they are presently only incompletely implemented by medical laboratories, neglecting MU of target values of internal quality control (IQC) materials.
Methods:
An empirical and practical approach for the estimation of MU based on the analysis of routine IQC using control samples with assigned target values is presented. Its feasibility is demonstrated exemplarily by analyzing IQC data from one year obtained for glucose employing the hexokinase method with IQC of two different concentrations.
Results:
Combined relative extended (k = 2) MU comprising bias, coefficient of variation (CV), and MU of the target values assigned to control materials were about 9% with a lower (~ 56 mg/dL; ~3.1 mmol/L) and 8% with a higher (~ 346 mg/dL; ~19.2 mmol/L) concentration sample, analyzing IQC of one year from three different devices.
Conclusions:
Estimation of MU in this study is quite reliable due to the large number of IQC data from one year. The MU of the target values of the commercial control material in this study was considerably larger than other MU contributions, ie, standard deviation and bias. In the future, the contribution of MU of commercial IQC should be addressed more carefully and technologies to measure glucose should be geared toward smaller MU possible, as needed, especially for glucose concentration measurements in diagnosis and management of DM.
Abstract
This work presents a stepwise reversible two‐electron transfer induced hydrogen shift leading to the conversion of a bis‐pyrrolinium cation to an E‐diaminoalkene and vice versa. Remarkably, the forward and the reverse reaction, which are both reversible, follow two completely different reaction pathways. Establishing such unprecedented property in this type of processes was possible by developing a novel synthetic route towards the starting dication. All intermediates involved in both the forward and the backward reactions were comprehensively characterized by a combination of spectroscopic, crystallographic, electrochemical, spectroelectrochemical, and theoretical methods. The presented synthetic route opens up new possibilities for the generation of multi‐pyrrolinium cation scaffold‐based organic redox systems, which constitute decidedly sought‐after molecules in contemporary chemistry.
Abstract
Certain hydrolases preferentially catalyze acyl transfer over hydrolysis in an aqueous environment. However, the molecular and structural reasons for this phenomenon are still unclear. Herein, we provide evidence that acyltransferase activity in esterases highly correlates with the hydrophobicity of the substrate‐binding pocket. A hydrophobicity scoring system developed in this work allows accurate prediction of promiscuous acyltransferase activity solely from the amino acid sequence of the cap domain. This concept was experimentally verified by systematic investigation of several homologous esterases, leading to the discovery of five novel promiscuous acyltransferases. We also developed a simple yet versatile colorimetric assay for rapid characterization of novel acyltransferases. This study demonstrates that promiscuous acyltransferase activity is not as rare as previously thought and provides access to a vast number of novel acyltransferases with diverse substrate specificity and potential applications.
The hirudin‐like factor 1 (HLF1) of Hirudo medicinalis belongs to a new class of leech‐derived factors. In previous investigations, HLF1 did not exhibit anticoagulatory activities. Here, we describe the analysis of natural and synthetic variants of HLF1 and HLF‐Hyb, a yet uncharacterized member of the HLF family. Modifications within the N terminus of HLF1 have a strong impact on its activity. Some variants of HLF1 exhibit thrombin‐inhibiting activity comparable to hirudins, whereas others have reduced or no activity. The analyses of HLF‐Hyb variants revealed a strong impact of the central globular domain on activity. Our results indicate a comparable mode of action of hirudins and thrombin‐inhibiting HLF variants. Finally, we propose and discuss criteria for classifying hirudins and HLFs.
Abstract
A device for the transaminase‐catalysed synthesis combined with continuous recovery of chiral amines was designed. The system enabled the separation of the reaction components in three liquid phases: a reaction phase, an organic solvent phase (where the poorly water soluble ketone substrate was supplied), and an aqueous extraction phase for continuous product recovery. The transaminase‐mediated asymmetric synthesis of (S)‐1‐methyl‐3‐phenylpropylamine was employed as model reaction. Factors influencing the performance of the system, such as reactor geometry, working volumes and operating parameters, were investigated. Specifically, reaction yield and product recovery were enhanced by i) reducing the thickness of the reaction phase, while continuously stirring and ii) reducing the volume of the extraction phase. Under the optimal condition tested, 85 % of the product formed was extracted and a product concentration value of 9 g/L was reached. However, co‐extraction of the unreacted amine donor (17 %) was observed. Advantages and drawbacks of this process compared to existing technologies, as well as possible optimization strategies are discussed.
The synthesis of several bioactive compounds and active pharmaceutical ingredients relies on the development of general and efficient methods to prepare optically pure amines. Transaminases are industrially relevant enzymes and are useful for synthesizing a large number of compounds that contain a chiral amine functionality. Although the immense potential associated to the use of these biocatalysts, the equilibrium position is often unfavorable for amine synthesis. The use of an excess of amine donor, compared to the ketone substrate, combined with selective removal of the formed product, can help in overcoming this limitation. This work mainly focused on broadening the application of membrane-based in situ product recovery (ISPR) techniques for the transaminase-catalyzed synthesis of chiral amines. The
overall work was designed around the implementation of amine donors, possessing considerably larger molecular ‘size’ compared to commonly used amine donors. To clearly
distinguish these molecules from traditional donor amines, we designate them as High Molecular Weigh amine donors. With a molecular weight between 400 and 1500 g/mol, in contrast to traditional donor amines, HMW amine donors enable a size-based separation between amine donor and amine product molecules. HMW amines, provided in excess for thermodynamic equilibrium shifting can thus be simply retained by a size-exclusion mechanism by commercial membranes, while the smaller product amines are permeated. Therefore, a selective recovery of the desired chiral amine product is possible. The implementation of ISPR techniques using HMW amine donors can theoretically lead to (i) equilibrium shifting, (ii) alleviation of product inhibition, and (iii) a highly pure product stream.
The feasibility of using HMW amine donors in aqueous, organic solvent and solvent-free media for the transaminase-catalyzed synthesis of 1-methyl-3-phenylpropylamine (MPPA) was proven in this thesis. The latter two approaches were investigated with the aim to achieve higher product concentrations. Along with that, we demonstrated two membrane-assisted ISPR proof of concepts. Specifically, nanofiltration was coupled with the enzymatic reaction performed in aqueous media (Article I), while liquid-liquid (L-L) extraction in a contactor was applied for transamination in organic solvent media (Article II). As an alternative to membrane-based strategies we also designed a spinning reactor concept for the integrated chiral amine synthesis (in organic solvent) and recovery (Article III).
Abstract
A N‐heterocyclic olefin (NHO), a terminal alkene selectively activates aromatic C−F bonds without the need of any additional catalyst. As a result, a straightforward methodology was developed for the formation of different fluoroaryl‐substituted alkenes in which the central carbon–carbon double bond is in a twisted geometry.
Molecular dynamics simulations to the bidirectional adhesion signaling pathway of integrin αVβ3
(2020)
Abstract
The bidirectional force transmission process of integrin through the cell membrane is still not well understood. Several possible mechanisms have been discussed in literature on the basis of experimental data, and in this study, we investigate these mechanisms by free and steered molecular dynamics simulations. For the first time, constant velocity pulling on the complete integrin molecule inside a dipalmitoyl‐phosphatidylcholine membrane is conducted. From the results, the most likely mechanism for inside‐out and outside‐in signaling is the switchblade model with further separation of the transmembrane helices.
G-quadruplexes (G4s) have been in the focus of research in the last decades for their regulatory roles in vivo and for their use in nano- and biotechnology. However, an understanding of the various factors that drive a particular quadruplex fold remains limited, challenging rational therapeutic targeting and design of these tetrahelical structures. In this regard, insights from modified G-quadruplexes may help to deepen our knowledge of G-quadruplex structure. In this dissertation, sugar-modified guanosine analogs are exploited for their altered conformational preferences regarding both glycosidic bond angle and sugar pucker by their incorporation into different syn positions of the G-core of a model G-quadruplex. Induced structural perturbations as characterized by NMR spectroscopy range from a local change in tetrad polarity to a complete refolding into an unusual structure with a V-shaped loop, a unique G4 structural element in the focus of this work. Detailed conformational analysis of the introduced G analogs and high-resolution structures of the modified quadruplexes reveal a complex interplay of glycosidic torsion angle, sugar pucker preferences and local interactions, which may all play a leading role in driving G4 folding.
Abstract
A DNA G‐quadruplex adopting a (3+1) hybrid structure was modified in two adjacent syn positions of the antiparallel strand with anti‐favoring 2′‐deoxy‐2′‐fluoro‐riboguanosine (FrG) analogues. The two substitutions promoted a structural rearrangement to a topology with the 5′‐terminal G residue located in the central tetrad and the two modified residues linked by a V‐shaped zero‐nucleotide loop. Strikingly, whereas a sugar pucker in the preferred north domain is found for both modified nucleotides, the FrG analogue preceding the V‐loop is forced to adopt the unfavored syn conformation in the new quadruplex fold. Apparently, a preferred C3′‐endo sugar pucker within the V‐loop architecture outweighs the propensity of the FrG analogue to adopt an anti glycosidic conformation. Refolding into a V‐loop topology is likewise observed for a sequence modified at corresponding positions with two riboguanosine substitutions. In contrast, 2′‐F‐arabinoguanosine analogues with their favored south‐east sugar conformation do not support formation of the V‐loop topology. Examination of known G‐quadruplexes with a V‐shaped loop highlights the critical role of the sugar conformation for this distinct structural motif.
Electrochemical characterisation of the redox behaviour of quinoide components in membrane models
(2020)
The leading idea of this thesis is to study the effects of (i) membrane composition and (ii) membrane environment (aqueous phases) on the redox properties of membrane-confined redox active compounds. For solutions, it is known since long, how strong solvents affect the redox properties of dissolved redox active species. However, for membranes this question has not yet been addressed, although it can be supposed that such effects may be important to understand the role of membrane-confined redox active compounds in biological systems. To interrogate this problem, a monolayer model was chosen. It consists of a lipid monolayer with embedded menaquinones on mercury electrodes. Since ion transfer across membranes is also a crucial question, in the first part of this project, 2,2-diphenyl-1-picrylhydrazyl (DPPH) was studied as a new redox probe for transferring anions and cation between an organic and an aqueous phase. The important findings of this thesis are: (i) accessing the ion pair equilibrium constant of anions and cations with DPPH redox probe as a model study using the three-phase electrochemistry, (ii) the redox potentials of menaquinone-4, -7, and -9 in 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) monolayers and the acidity constants of menaquinones (MK’s) in membranes monolayer model, and (iii) the effects of membrane composition and the aqueous environment on the thermodynamics and kinetics of MK’s in membrane models.
Aufgrund der extremen Instabilität des Molybdän Cofaktors (MoCo) ist eine genauere Untersuchung der aktiven Zentren der lebenswichtigen MoCo-abhängigen Enzyme allein durch biochemische Methoden fast unmöglich. Hierfür liefert eine chemische Modellierung des Cofaktors die einzige Möglichkeit einen tieferen Einblick in seine Struktur und Funktion.
Die vorliegende Dissertation ermöglicht einen weitaus tieferen Einblick in Struktur-Funktionsbeziehung des Molybdän-Cofaktors hinsichtlich des zentralen Metalls und des Molybdopterin-Liganden. Zunächst wurde die Rolle des Molybdänzentrums in den Modellverbindungen detailliert analysiert. Hierfür wurde in den synthetisierten Modellen Molybdän mit Rhenium, ausgetauscht. Die erhaltenen Komplexe wurden zuerst umfangreichend durch verschiedene Methoden Kristallstrukturanalyse, IR-, Raman-, NMR-, 2D-NMR-Spektroskopie, temperaturabhängige Elektrochemie und quantenchemischen Berechnungen analysiert und auf Analogien und Unterschiede verglichen. Dabei wurde auf der Suche eines MoCo-Modells, das die richtige Balance zwischen katalytischer Aktivität und Stabilität besitzt, untersucht, ob Rhenium eine potenzielle Alternative zu Molybdän darstellen kann.
Um einen tieferen Einblick in die Chemie des Pterin-Strukturabschnitts von MoCo zu erschaffen, beschäftigt sich diese Arbeit mit der Feinabstimmung von Chinoxalin- und Pterin-Dithiolen-Liganden sowie mit der Entwicklung deren Molybdän-Komplexen. Dazu konnten neuartige Chinoxalin- und Pterin-Dithiolen-Liganden synthetisiert werden, die als Modell-Liganden für die Erforschung der Biosynthese des MoCos fungieren können. Hierin wird die Synthese und die vollständige Charakterisierung eines neuartigen Oxo-Bis(pterin)dithiolen-Molybdän-Komplexes beschrieben. Durch 2D-NMR Spektroskopie konnte die Struktur des erhaltenen Komplexes in Lösung detailliert analysiert werden. Schließlich wurden im Rahmen der vorliegenden Arbeit erstmals durchgeführte Untersuchungen zur Bindung von chemisch synthetisierten MoCo-Modellen mit dem Apoenzym der Trimethylamin-N-Oxid-Reduktase unternommen. Dabei konnte die essenzielle Rolle des Pterin-Gerüstes für die richtige Platzierung des Cofaktors in der Bindungstasche des Apoenzyms etwas näher aufgeklärt werden. Zukünftig könnten noch strukturell genauere MoCo-Modelle den Weg für die Synthese einer semi-artifiziellen Sulfitoxidase, die als eine Behandlungsmöglichkeit der Molybdän-Cofaktor-Defizienz (MoCoD) und der isolierten Sulfitoxidase-Defizienz (iSOD) eingesetzt werden, eröffnen.
In contrast to its terrestrial counterpart, the metabolic degradation of marine polysaccharides is underexplored. This work aimed to functionally characterize ulvan- and xylan-degrading enzymes from marine Bacteroidetes in order to clarify the metabolic degradation pathway. For the provision of a broad polysaccharide substrate spectrum, ulvan from several different algal sources was extracted to be used in further characterization experiments. The structural differences of these ulvans could be demonstrated by enzymatic degradation with ulvan-active enzymes. In order to clarify the synergistic catalytic effects of polysaccharide sulfatases with GHs in the degradation process of ulvan, several putative sulfatases from F. agariphila were produced recombinantly in E. coli. For that, a coexpression with an FGE encoding gene was required. It could be demonstrated that several glycoside hydrolases are inhibited, if their
substrate is sulfated at the cleavage position and that a previous desulfation using one of the sulfatases enabled the further degradation. Some of the sulfatases showed an endolytic or exolytic cleavage behavior like reported for several GHs. With the combined catalytic activities, it was possible to successfully elucidate the complex ulvan degradation mechanism for the first time, which enables the use of ulvan as a biotechnological source for the production of fine chemicals and pharmaceuticals. This degradation mechanism was shown to be complemented by an alternative pathway that helps with the degradation of uronic acid-containing oligosaccharides. Here, the synergistic effects of a multimodular enzyme containing a sulfatase and rhamnosidase domain were demonstrated. Furthermore, the first dehydratase participating in the degradation of oligosaccharides was revealed. The functional characterization of putative xylan-targeting PULs from two Flavobacteriia revealed the existence of marine endolytic and exolytic xylanases. The enzymes of these PULs were produced recombinantly in E. coli and were used in biocatalysis reactions on xylan from beechwood, xylan from P. palmata or commercial xylooligosaccharide standards. Further side chain-active GHs were found to exclusively be active on either standards or xylan. The great variation of genetic equipment was demonstrated by comparing the enzyme activities of these PUL structures assuming different ecological adaptations of these organisms especially, because these PULs do not code for any putative sulfatases, which is uncommon for PULs targeting xylan. A different degradation behavior of the investigated enzymes suggested a preferred conversion of β-1,4-linked xylan, potentially present in some microalgae. The acquired insight of the metabolic ulvan and xylan utilization greatly expands the scientific knowledge about the ecologic interplays in marine environments concerning the polysaccharide utilization. It indicates the necessity of backup mechanisms for metabolic processes in order to get access to complex marine carbon sources in nature. Several small degradation cascades complement each other to break down substrate compounds to monomeric level for the use of structurally diverse polysaccharides. This expands the insights into the metabolic processes in the degradation of marine polysaccharides, which are an important part of the understanding of the ecological interactions in aquatic habitats and the ocean’s carbon cycle.
The characterization of ulvan- and xylan-active enzymes and the clarification of their substrate scopes allow to use these enzymes in future production of carbohydrate-derived chemical products for many industrial applications, making it possible to use algal waste for recycling to high value materials with even beneficial effect for the environment.
Abstract
Over the last years, there has been an enormous increase in the knowledge on koi herpesvirus (KHV), koi herpesvirus disease (KHVD), pathogenesis and virus variants. Different KHV lineages have clearly been identified, possible genomic changes during replication in different cell cultures at different temperatures but also in several hosts have been identified, a persistent stage of infection has been specified and it has been shown that infection with KHV is not host specific at all, but KHVD is. Additionally, it has been shown that it is possible to combat KHVD by immunization with inactivated and attenuated live vaccines using different delivery systems but also to benefit from alternative treatments with e.g. exopolysaccharids obtained from Arthrospira platensis.
Abstract
Environmentally‐friendly processes for the manufacturing of valuable industrial compounds like ω‐hydroxy fatty acids (ω‐OHFAs) are highly desirable. Herein, we present such an approach by establishing a two‐step enzymatic cascade reaction for the production of 2,15,16‐trihydroxy hexadecanoic acid (THA). Starting with the easily accessible natural compound ustilagic acid (UA) that is secreted by the corn smut fungus Ustilago maydis, the recombinantly expressed esterase BS2 from Bacillus subtilis and the commercial β‐glucosidase from almonds were applied yielding 86 % product. Both hydrolases do not require expensive cofactors, making the process economically attractive. Additionally, no harmful solvents are required, so that the product THA can be labelled natural to be used in food and cosmetic products.
In modern-day organic synthesis, transitional metal catalysis has become an essential tool-kit to access the biologically significant complex organic scaffolds. The activation profile of these sophisticated catalytic systems in cross-coupling chemistry and ring-closing processes has been well appreciated and frequently employed by the scientific community.
The present thesis is describing the results of interdisciplinary research involving medicinal chemistry and transitional metal homogeneous catalysis. A molybdenum mediated process was employed to access 32 unprecedented heterocyclic fused poly sulfur ring containing pentathiepins in moderate to good yields as a part of medicinal chemistry. Biologically significant, such as quinoxaline, pyrazine, pyridine, nicotinamide, quinoline, imdazo-pyrazine, pyrrolo-pyrazine, purine, and pyridine sulfonamide scaffolds were functionalized with pentathiepin unit via multi-step organic synthesis. Essentially, the Sonogashira cross-coupling and(Et4N)2[MoO(S4)2] mediated ring-closing steps were commonly employed in all pentathiepin syntheses. The analytically pure samples were characterized by 1H, 13C, 19F-NMR, FTIR, ESI-MS, CHNS, and X-ray single-crystal diffraction analysis. Notably, all pentathiepins exhibited an ABX3 multiplet pattern between δ: 4.2-4.5 ppm with the integration of 2H for the ethoxy functional group's methylene protons substituted on the five-membered ring of pentathiepin, which was later considered as a fingerprint for pentathiepin formation. The mechanistic investigations via control experiments suggest that the tetra sulfur ring Mo(IV) precursor (Et4N)2[MoO(S4)2] is vital along with elemental sulfur for the pentathiepin formation, and the Mo(IV) complex regenerates in the reaction. Furthermore, For the first time, the GPx1 enzyme inhibitor properties of novel fused heterocyclic pentathiepins were established, where these probes exhibited 9-12 folds higher potency than mercaptosuccinic acid. Notably, <1 µM concentration of quinoxaline, pyrazine, and quinoline fused pentathiepins were potent enough to inhibit 50% of GPx1 enzyme activity. Additionally, cytotoxicity, antimicrobial and antifungal studies were conducted for all pentathiepins. In anticancer investigations, the IC50 concentrations for all pentathiepins were ranging between 0.22 to 4.7 µM.
The second half of the thesis introduces a novel water-soluble Pd/PTABS as a potent catalyst for C-X (X = N, O, and S) cross-coupling chloroheteroarenes and halonucleosides. The novel, mild and efficient Pd/PTABS catalytic system was successfully employed at low catalytic loadings (1 mol%) for the amination (C−N), etherification (C−O), and thioetherification (C−S) of chloroheteroarenes at ambient to moderate temperatures. The Pd/PTABS catalyst is well-tolerating various heterocyclic scaffolds, and under the optimized catalytic conditions, various secondary amines, electron-rich or electron-poor phenols, thiophenols, and alkylthiols, were efficiently employed as nucleophilic coupling partners. Notably, the catalyst offered tremendous regio and chemoselectivity with excellent temperature control. Besides, novel sulfones and sulfoximines were prepared from the thioethers obtained via Pd/PTABS. The catalyst was employed efficiently for synthesizing biologically significant known drugs or drug candidates such as alogliptin (anti-diabetic agent), XRK 469 (antitumor agent), and Imuran-Azathioprine (immunosuppressive) in competitive yields. Preliminary DFT investigations were performed, and based on the DFT analysis, the electropositive character of the phosphorous atom in quaternary ammonium salts of PTABS supports the heteroatom directed C−Cl activation hypothesis.
An Ultrasensitive Fluorescence Assay for the Detection of Halides and Enzymatic Dehalogenation
(2020)
Abstract
Halide assays are important for the study of enzymatic dehalogenation, a topic of great industrial and scientific importance. Here we describe the development of a very sensitive halide assay that can detect less than a picomole of bromide ions, making it very useful for quantifying enzymatic dehalogenation products. Halides are oxidised under mild conditions using the vanadium‐dependent chloroperoxidase from Curvularia inaequalis, forming hypohalous acids that are detected using aminophenyl fluorescein. The assay is up to three orders of magnitude more sensitive than currently available alternatives, with detection limits of 20 nM for bromide and 1 μM for chloride and iodide. We demonstrate that the assay can be used to determine specific activities of dehalogenases and validate this by comparison to a well‐established GC‐MS method. This new assay will facilitate the identification and characterisation of novel dehalogenases and may also be of interest to those studying other halide‐producing enzymes.
Herein, we report the synthesis of a series of push–pull imines by considering cyclic diamino substituent at the C‐centre and fluoroaryl substituent at the N‐centre. This has been achieved by a selective aromatic nucleophilic substitution of different fluoroarenes by N‐H‐substituted N‐heterocyclic imines (NHIs) at ambient conditions without any additional reagent. Solid‐state molecular structure analysis reveals the elongation of the central C–N bond of the imine functionality, which is consistent with the push–pull nature of these imines. The push–pull nature of these imines is further validated by computational studies.