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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.
Fast screening of enzyme variants is crucial for tailoring biocatalysts for the asymmetric synthesis of non-natural chiral chemicals, such as amines. However, most existing screening methods either are limited by the throughput or require specialized equipment. Herein, we report a simple, high-throughput, low-equipment dependent, and generally applicable growth selection system for engineering amine-forming or converting enzymes and apply it to improve biocatalysts belonging to three different enzyme classes. This results in (i) an amine transaminase variant with 110-fold increased specific activity for the asymmetric synthesis of the chiral amine intermediate of Linagliptin; (ii) a 270-fold improved monoamine oxidase to prepare the chiral amine intermediate of Cinacalcet by deracemization; and (iii) an ammonia lyase variant with a 26-fold increased activity in the asymmetric synthesis of a non-natural amino acid. Our growth selection system is adaptable to different enzyme classes, varying levels of enzyme activities, and thus a flexible tool for various stages of an engineering campaign.
The vast majority of RNA splicing in today‘s organisms is achieved by the highly regulated and precise removal of introns from pre-mRNAs via the spliceosome. Here we present a model of how RNA splicing may have occurred in earlier life forms. We have designed a hairpin ribozyme derived spliceozyme that mediates two RNA cleavages and one ligation event at specific positions and thus cuts a segment (intron) out of a parent RNA and ligates the remaining fragments (exons). The cut-out intron then performs a downstream function, acting as a positive regulator of the activity of a bipartite DNAzyme. This simple scenario shows how small RNAs can perform complex RNA processing dynamics, involving the generation of new phenotypes by restructuring segments of given RNA species, as well as delivering small RNAs that may play a functional role in downstream processes.
A highly stereoselective recombinant alcohol dehydrogenase aus 'Pseudomonas fluorescens' DSM50106
(2005)
The alcohol dehydrogenase was biochemically characterized. A broad range of arylaliphatic ketones is efficiently reduced to the corresponding optically active (R)-alcohols by a recombinant alcohol dehydrogenase (PF-ADH) produced by overexpression in 'Escherichia coli'. PF-ADH shows high activity and stereoselectivity in the reduction of acetophenone and various derivatives (45-99%), as well as in the reduction of 3-oxy-butyric acid methyl ester and 3-oxy-butyric acid methyl ester and 3-oxy-hexanoic acid ethyl ester (>99%). The highest activity was observed between 10 and 20°C. The copfactor NADH can be efficiently recycled by the addition of 10-20% of iso-propanol. A flow-through-polarimetry-based assay to determine oxidoreductase activity and stereoselectivity is described.
Introduction
Neurofilament light (NfL) can be detected in blood of healthy individuals and at elevated levels in those with different neurological diseases. We investigated if the choice of biological matrix can affect results when using NfL as biomarker in epidemiological studies.
Method
We obtained paired serum and EDTA-plasma samples of 299 individuals aged 37–67 years (BiDirect study) and serum samples of 373 individuals aged 65–83 years (MEMO study). In BiDirect, Passing–Bablok analyses were performed to assess proportional and systematic differences between biological matrices. Associations between serum or EDTA-plasma NfL and renal function (serum creatinine, serum cystatin C, glomerular filtration rate, and kidney disease) were investigated using linear or logistic regression, respectively. All regression coefficients were estimated (1) per one ng/L increase and (2) per one standard deviation increase (standardization using z-scores). In MEMO, regression coefficients were estimated (1) per one ng/L increase of serum or calculated EDTA-plasma NfL and (2) per one standard deviation increase providing a comparison to the results from BiDirect.
Results
We found proportional and systematic differences between paired NfL measurements in BiDirect, i.e., serum NfL [ng/L] = −0.33 [ng/L] + 1.11 × EDTA-plasma NfL [ng/L]. Linear regression coefficients for the associations between NfL and renal function did not vary between the different NfL measurements. In MEMO, one standard deviation increase in serum NfL was associated with greater changes in the outcomes than in BiDirect.
Conclusion
Although there are differences between serum and EDTA-plasma NfL, results can be used interchangeably if standardized values are used.
Understanding the fundamental mechanisms in the extracellular matrix of cells (ECM) is crucial for the development of drugs and biomaterials. Therefore, an atomistic model of the extracellular matrix is a cost-efficient way to observe influences of drugs, test the effect of mutations or misfolds in proteins or study the properties of fibril or network-forming peptides.
With this thesis, a refined molecular model of an adhesion complex is proposed that contains collagen, fibronectin and the cell receptor integrin. During the building of the model, major new insights are given for each of these proteins and a powerful protein-folding algorithm is
developed.
The transition to Ni‐based battery cathodes enhances the energy density and reduces the cost of batteries. However, this comes at the expense of losing energy efficiency which could be a consequence of charge–discharge hysteresis. Here, a thermodynamic model is developed to understand the extent and origin of charge–discharge hysteresis in battery cathodes based on their cyclic voltammograms (CVs). This was possible by defining a Gibbs energy function that weights random ion insertion/expulsion, i. e., a solid solution pathway, against selective ion insertion/expulsion, i. e., a phase separation route. The model was verified experimentally by the CVs of CoOOH and Ni(OH)2 as solid‐solution and phase‐separating cathodes, respectively. Finally, a microscopic view reveals that phase separation and hysteresis are a consequence of large ionic radii difference of the reduced and oxidized central metal atoms.
The potential of several ion-sensitive electrodes responds to the incorporated cations and anions. This has led some authors to misinterpret the potential of metal salt membrane electrodes and of electrodes of the second kind. Neglecting the kinetics of potential establishment and interpreting the potentials solely based on thermodynamics produce completely irrelevant data and suggest that ion concentrations down to 10−45 mol L−1 are accessible by simple potentiometric measurements. The switching from cation to anion response mechanism cannot be derived from thermodynamic equations. It bears complete similarity to the switching of response in the case of foreign interfering ions.
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.
Abstract
Amine transaminases (ATAs) are biocatalysts for the synthesis of chiral amines and can be identified in sequence databases by specific sequence motifs. This study shows that the activity level towards the model substrate 1‐phenylethylamine can be predicted solely from the sequence. To demonstrate this, 15 putative ATAs with a different distribution of hydrophobic or hydrophilic amino acid side chains near the active site were characterized. Hydrophobic side chains were associated with a high activity level and were a better predictor of activity than global sequence identity to known ATAs with high or low activities. Enzyme stability investigations revealed that four out of the 15 ATAs showed a good operational stability.
We are currently facing an antimicrobial resistance crisis, which means that a lot of bacterial pathogens have developed resistance to common antibiotics. Hence, novel and innovative solutions are urgently needed to combat resistant human pathogens. A new source of antimicrobial compounds could be bacterial volatiles. Volatiles are ubiquitous produced, chemically divers and playing essential roles in intra- and interspecies interactions like communication and antimicrobial defense. In the last years, an increasing number of studies showed bioactivities of bacterial volatiles, including antibacterial, antifungal and anti-oomycete activities, indicating bacterial volatiles as an exciting source for novel antimicrobial compounds. In this review we introduce the chemical diversity of bacterial volatiles, their antimicrobial activities and methods for testing this activity. Concluding, we discuss the possibility of using antimicrobial volatiles to antagonize the antimicrobial resistance crisis.
In their idealized forms, enzymes can facilitate complex reactions with extreme specificity and selectivity. Additionally, in this imaginative form, they only require mild reaction conditions, resulting in low energy consumption, and they are biodegradable, efficient, reusable, and sustainable. Unfortunately, this idealized form often deviates significantly from reality, where enzymes are more likely to be associated with marginal stability and low reaction rates, leaving them less than desirable for many industrial applications. As such, if we could master the process of engineering the configuration of a protein towards a given task, the implications could be staggering.
This thesis aims to contribute to the process of protein engineering, mainly how computational tools can be used to make the protein engineering process more efficient and accessible.
Article I explores the current state of the art in machine learning-guided directed evolution and serves as a foundation for Article II, which is a concrete application of these techniques to an engineering campaign. Despite successfully improving overall activity and selectivity, we also observe limitations and constraints within the methodology. Article III then delves into these drawbacks and attempts to lay the foundation for a more generalizable and, more importantly, efficient engineering workflow, balancing the strengths and weaknesses of computational techniques with advances in gene synthesis. We then validated this novel pipeline in Article IV, where we show the potential of this methodology. Article V describes a more standard protein engineering campaign on squalene-hopene cyclases for potentially interesting products in the flavor and fragrance industry. Lastly, Article VI outlines a PyMol plugin for molecular docking.
Im Rahmen dieser Arbeit wurden neuartige alpha-Phosphanylaminosäuren untersucht. Die Verbindungen wurden durch eine Dreikomponenten-Eintopfreaktion bei Raumtemperatur aus Diphenylphosphan, einem primären Amin und Glyoxylsäure hergestellt. Alle Verbindungen sind luftempfindlich und bilden in Lösung langsam Zersetzungsprodukte. Es wurden P-Sulfide, P-Oxide und P-Pentacarbonylmetall(0)komplexe hergestellt, Versuche zur Synthese von BH3-Addukten in Molverhältnis 1:1 und 1:3 durchgeführt. Das enantiomerenreine 1-(p-methoxyphenyl)ethyl-substituierte Phosphanylglycin wurde als Ligand auf Eignung in enantioselektiven, katalytischen Hydrierungen verschiedener alpha-, beta-ungesättigter Ketoverbindungen untersucht. Sieben Verbindungen aus verschiedenen Gruppen N-substituierter Phosphanylglycine wurden als Liganden mit Ni(COD)2 zu in situ in Katalysatoren umgesetzt und damit die Poly/Oligomerisation von Ethylen untersucht. Die meisten untersuchten Liganden bewirkten hohe katalytische Umsätze von Ethylen und zeigten somit gute Eignung als Liganden zur Stabilisierung aktiver Ni-Oligomerisationskatalysatoren.
The widespread use of natural and synthetic estrogens or chemicals with estrogenic activities is causing an increasing accumulation of estrogenic compounds in the environment. Already at very low concentrations these estrogenics can severely affect the wildlife, particularly in an aquatic environment. For these reasons measuring devices for detecting estrogen contaminations are in great demand. The majority of the analytical methods and bioassays on the market so far, lack semi-online adaptability, and usually cannot be used for automatic and continuous determination. Therefore, we have embarked on the development of new systems, which are able to fulfil those demands. The EstraMonitor combines recombinant A. adeninivorans G1212/YRC102-hERa-phyK yeast cells as the microbial component with an amperometric detection method to analyze estrogenic contaminations. A. adeninivorans G1212/YRC102-hERa-phyK was constructed by Kaiser et al. (2010). These cells were engineered to co-express the human estrogen receptor (hERa) gene and the inducible phytase (phyK, derived from Klebsiella sp. ASR1) reporter gene under control of a promoter with estrogen response elements (EREs). In the presence of estrogenic substances, such as 17ß -estradiol (E2), the phyK gene is expressed and recombinant phytase is secreted into the media. The level of phytase is quantified by amperometric detection using substrate p-aminophenyl phosphate (p-APP). Phytase dephosphorylates p-aminophenyl phosphate (p-APP) into an intermediate product p-aminophenol (p-AP). p-AP is electroactive and oxidized at the electrode. This generates electrons and produces a current which is proportional to the level of phytase activity. Since phytase activity is directly correlated to the E2 concentration, the estrogenic activity can thus be calculated from the current measured. The microbial component of the EstraMonitor, the non-immobilized A. adeninivorans G1212/YRC102-hERa-phyK, works well with the amperometric method in a quantitative manner. The optimal applied potential determined for amperometric measurements was 150 mV and provided a low background signal for the amperometric detection. The half maximal effective concentration (EC50) and limit of detection (LoD) values for E2 obtained from amperometric measurements with the EstraMonitor were 69.9 ng L-1 and 44.5 ng L-1, respectively. The measuring procedure of the EstraMonitor system including incubation of A. adeninivorans G1212/YRC102-hERa-phyK cells with E2, subsequently incubation with electrochemical substrate (p-APP), and signal recordation is completed within only 4 h and 10 min. Out of this total time, amperometric detection including substrate incubation and signals recordation takes only 10 min out of total time. The use of immobilized cells for a microbial biosensor is an essential advantage of the EstraMonitor system because it allows easy-handiness next to long-term stability and reusability. Immobilized A. adeninivorans G1212/YRC102-hERa-phyK cells revealed excellent properties which make them very suitable for semi-online, automatic and continuous monitoring. They were stable up to 30 days when stored at 4 °C. Furthermore, they could be reused up to 15 times. The EC50 and LoD values achieved for E2 using immobilized cells in combination with amperometric detection were 20.9 and 8.3 ng L-1, respectively. Furthermore, this application also removes the need to separate cells by centrifugation, to sterilize the samples as well as to cultivate repeatly. Additionally, both immobilized and non-immobilized A. adeninivorans G1212/YRC102-hERa-phyK cells remain fully functional in a wide range of untreated wastewater samples and in environments containing up to 5% NaCl. To enhance the sensitivity and reduce the time for estrogenic determination, an alternative A. adeninivorans G1214/YRC103-hERa-phyK strain was developed. This strain can produce a detectable amount of phytase within 2 h after induction with E2. It offers an improved microbial component in terms of sensitivity and time-effectiveness. In addition, to reduce the cost for estrogenic detection an alternative substrate, ascorbic acid 2-phosphate (AA2P), was tested. AA2P, which is both cheap and widely available, performed better than p-APP. The EC50 and LoD values for E2 obtained with AA2P were 15.69 and 0.92 ng L-1 versus 20.09 and 8.3 ng L-1 when examined with p-APP, respectively. Taken together, the EstraMonitor is an automated system with respect to sample cycling, sample measuring and calibration supplemented with an alarm function. This system makes it possible to control estrogenic activity semi-online, automatically and continuously. These are advantages of the EstraMonitor compared to other estrogenic detection systems. It can thus be concluded that, the EstraMonitor is a powerful and feasible semi-online device for monitoring estrogenic activity especially adapted for the use in sewage treatment plants.
In this thesis an artificial enzyme cascade consisting of an ADH from Lactobacillus kefir, a CHMO from Acinetobacter sp. NCIMB 9871 and lipase A from Candida antarctica has been investigated for the biocatalytic synthesis of the bulk chemical ε-caprolactone as well as several derivatives for their direct utilization as polymer building blocks. Due to major limitations, which hamper such a biocatalytic route, the first addressed demand in this work was the improvement of the stability of the CHMO. By structure-guided engineering, distinctively improved variants concerning the resistance against oxidation as well as temperature stability without compromising the catalytic activity were successfully created. Due to the incomplete knowledge of the mechanisms that lead to thermal and/or oxidative inactivation of enzymes, this study illustrates that the selection of mutations for increased protein stability is still hard to predict. Thus, these results can serve as a basis for further stability studies on this enzyme class to give better insights into the underlying mechanisms, which determine the stability of an enzyme. Such a highly stabilized biocatalyst will pave the way for the successful use of flavin-dependent enzymes for industrial applications. A further aim of this thesis was dedicated to the second major hurdle en route to polyester precursors represented by the product inhibition and enzyme deactivation caused by ε-caprolactone, particularly at higher concentrations. To overcome this limitation, we developed an elegant solution in which the ε-caprolactone produced by the one-pot two-step enzymatic method is directly subjected to ring-opening polymerization using the unique lipase A from Candida antarctica. Applying this enzyme cascade in a whole cell biocatalysis in combination with an improved cofactor regeneration approach, the problem of product inhibition problem was efficiently solved leading to the formation of oligo-ε-caprolactone at more than 20 g/L when starting from 200 mM cyclohexanol. By a process development approach through solvent engineering it was found that biotransformations proceed much faster in an isooctane-containing biphasic solvent system when using free enzymes. Finally, the improved enzyme cascade was applied for the synthesis of chiral substrates and provided access to functionalized chiral compounds in high yields (up to >99%) and optical purities (up to >99%ee). By subsequent enzymatic enantioselective ring-opening of the enantiopure monomers, oligomeric lactones were successfully synthesized, which can be directly serve as building blocks for the polymer industry.
An Enzyme Cascade Reaction for the Recovery of Hydroxytyrosol Dervatives from Olive Mill Wastewater
(2022)
Abstract
The valorization of olive mill wastewaters (OMWW), a by‐product of the olive milling, is getting rising attention. Lipophilization of the main phenolic compound 3‐hydroxytyrosol (HT) could facilitate its extraction. An immobilized variant of the promiscuous hydrolase/acyltransferase from Pyrobaculum calidifontis VA1 (PestE) was used to perform acetylation in water using ethyl acetate as acyl donor. PestE was used in a segmented flow setting to allow continuous operation. Additionally, HT precursors were made accessible by pretreatment with almond β‐glucosidase and the hydrolytic activity of PestE_I208A_L209F_N288A.
Electrochemical Raman spectroscopy can provide valuable insights into electrochemical reaction mechanisms. However, it also shows various pitfalls and challenges. This paper gives an overview of the necessary theoretical background, crucial practical considerations for successful measurement, and guidance for in situ/in operando electrochemical Raman spectroscopy. Several parameters must be optimized for suitable reaction and measurement conditions. From the experimental side, considerations for the setup, suitable signal enhancement methods, choice of material, laser, and objective lens are discussed. Different interface phenomena are reviewed in the context of data interpretation and evaluation.
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.
Analyse der metabolischen Anpassung von Streptococcus pneumoniae an antimikrobielle Umwelteinflüsse
(2019)
Das Gram-positive Bakterium Streptococcus pneumoniae ist ein humanspezifisches Pathogen des oberen Respirationstraktes. Der opportunistische Krankheitserreger kann jedoch mehrere Organe befallen und tiefer in den Körper vordringen, was zu lokalen Entzündungen wie Sinusitis und Otitis media oder zu lebensbedrohlichen Infektionen wie Pneumonie, Meningitis oder Sepsis führen kann. Für das Bakterium S. pneumoniae wurden bisher kaum Metabolom-Daten erhoben. Daher war das Ziel dieser Dissertation eine umfassende Charakterisierung des Metaboloms von S. pneumoniae. In dieser Dissertation wurden als analytische Methoden die Gaschromatografie (GC) und Flüssigkeitschromatografie (LC) jeweils gekoppelt mit Massenspektrometrie (MS) sowie die Kernspinresonanzspektroskopie (NMR) verwendet, um die Metaboliten zu analysieren. Es sind mehrere Analysetechniken erforderlich, um den Großteil des Metaboloms mit seinen chemisch verschiedenen Metaboliten zu erfassen. Artikel I fasst die Literatur zu Untersuchungen des Metabolismus von S. pneumoniae in den letzten Jahren zusammen. Um eine Momentaufnahme des biologischen Systems zum jeweiligen Zeitpunkt zu erhalten, ist neben dem reproduzierbaren Wachstum während der Kultivierung auch die exakte Probenahme zu beachten. Aus diesem Grund wurde in dieser Dissertation ein Probenahmeprotokoll für das Endometabolom von S. pneumoniae etabliert (Artikel II). Mithilfe des optimierten Protokolls wurde eine umfassende Metabolomanalyse in einem chemisch definierten Medium durchgeführt (Artikel II). Um S. pneumoniae in einer Umgebung ähnlich der im Wirt zu untersuchen, wurde in einem modifizierten Zellkulturmedium kultiviert. Intermediate zentraler Stoffwechselwege von S. pneumoniae wurden analysiert. Das intrazelluläre Stoffwechselprofil wies auf einen hohen glykolytischen Flux hin und bot Einblicke in den Peptidoglykan-Stoffwechsel. Darüber hinaus widerspiegelten die Ergebnisse die biochemische Abhängigkeit von S. pneumoniae von aus dem Wirt stammenden Nährstoffen. Ein umfassendes Verständnis der Stoffwechselwege von Pathogenen ist wichtig, um Erkenntnisse über die Anpassungsstrategien während einer Infektion zu gewinnen und so neue Angriffspunkte für Wirkstoffe zu identifizieren.
Die zunehmende Verbreitung von resistenten S. pneumoniae-Stämmen zwingt zur Suche nach neuen antibiotisch wirksamen Substanzen. Im Zuge dessen wurde in Artikel III die metabolische Reaktion von S. pneumoniae während des Wachstums unter dem Einfluss antibakterieller Substanzen mit dem Ziel der Identifizierung metabolischer Anpassungsprozesse untersucht. Dabei wurden Antibiotika mit unterschiedlichen Wirkmechanismen verwendet, wie die Beeinflussung der Zellwandbiosynthese (Cefotaxim, Teixobactin-Arg10), der Proteinbiosynthese (Azithromycin) sowie Nukleotidsynthese (Moxifloxacin). Es konnten keine Wirkmechanismus-spezifischen Marker-Metaboliten identifiziert werden. Jedes Antibiotikum verursachte weitreichende Veränderungen im gesamten Metabolom von S. pneumoniae. Die Nukleotid- und Zellwandsynthese waren am stärksten betroffen. Besonders vielversprechend sind Antibiotika mit zwei Wirkorten wie Teixobactin-Arg10 und Kombinationen aus zwei Antibiotika. In dieser Dissertation wurde das erste Mal das synthetisch hergestellte Teixobactin-Arg10 mittels einer der modernen OMICS-Techniken untersucht. Die vorliegende umfassende Metabolom-Studie bietet wertvolle Erkenntnisse für Forscher, die an der Identifizierung neuer antibakterieller Substanzen arbeiten.
Insgesamt tragen die Ergebnisse der Dissertation zu einem besseren Verständnis der bakteriellen Physiologie bei.
Analysis of bioactive lipids from different infection models during bacterial and viral infections
(2021)
Bioactive lipids or lipid mediators influence numerous processes like the reproduction, the bone turnover, the pain perception, the cardiovascular function and the immune system. Eicosanoids and oxylipins are parts of the immunomodulatory lipid mediators, which can be synthesized from polyunsaturated fatty acids (PUFAs) by enzymatic and non-enzymatic reactions. Typical members of eicosanoids are prostaglandins and leukotrienes. The properties of bioactive lipids include the activation of inflammatory reactions as well as the support of resolution. Like hormones, they act locally restricted and in low concentrations. Further bioactive lipids exist i.e. intermediates of the sphingolipid class. The biosynthesis of some of these compounds like the prostaglandins can be influenced by different drugs whereas for other groups of lipid selective inhibitors are still missing. Their impact on inflammatory processes and against chronic diseases has already been analyzed, while studies in context with infection are largely limited. Infection of the upper respiratory tract caused by viral and bacterial pathogens constitute a huge burden for the human healthcare. The main pathogens are the Influenza A virus (IAV), Staphylococcus aureus (S. aureus), Streptococcus pneumoniae (S. pneumoniae) and Streptococcus pyogenes (S. pyogenes). Besides mono-infection with one of these pathogens, frequently occurring bacto-viral co-infections exist, which negatively influence the etiopathology. The main task of the immune system is the detection and the elimination of pathogens, which can essentially be affected by lipid mediators. Their instability due to oxidizability, the existence of regioisomers and the low abundance of eicosanoids and other oxylipins are the main problems for their analytical measurement.
The mayor objective of this dissertation was the establishment of a suitable analytical method for selected lipid mediators and the detection of infection-related changes. The separation and detection was performed by using high-performance liquid chromatography (HPLC) coupled with triple quad mass spectrometry. This combination is called tandem mass spectrometry (MS/MS). The MS parameters were optimized for approximately 30 lipid mediators by use of chemical standards and the detection was achieved by dynamic multiple reaction monitoring (MRM). Furthermore, the spatial resolution of selected sphingolipids was analyzed in tissue samples using matrix-assisted laser desorption ionization mass spectrometry imaging (MALDI-MS-Imaging). Concerning the HPLC-MS/MS detection, an MS method was established and optimized with standard compounds. Another crucial part of the establishment was the extraction of bioactive lipids from the different sampling materials. Whereas well tested protocols exist for the extraction and detection of lipid mediators, such protocols for MALDI-MS-Imaging are still limited due to the novelty of this measurement. Ultimately, robust and reproducible protocols for both techniques that were used for the analysis of a broad array of samples from infection experiments were established for both techniques. The analyses of infected cell culture, mice and pigs revealed infection-related perturbations of host lipid mediator levels. Depending on the scientific issue, the sample types cell pellets, lungs, spleens, livers, blood plasmas, pawns including bones or bronchoalveolar lavages were analyzed. For MALDI-MS-Imaging, the spatial distribution of sphingolipids in lung and spleen was detected.
The present dissertation includes four coherent research scopes, in which the pathogen impact on host-derived lipid mediators was detected with the above mentioned analytical methods. The infection models epithelial cells (article II), mouse (article III and IV) and pig (article I) – the latter as the most human like model - showed different aspects of the host-pathogen interaction. The analysis of samples from IAV infection for all three hosts revealed a couple of similarities for some oxylipins that were also described in human infections. Additionally, cell culture and mouse samples from mono-infections as well as co-infections with the pathogens S. aureus and S. pneumoniae were measured. In particular for the bacterial mono- and co-infections, these are the first published results with aspects of infection related changes of lipid mediators. The additional spatial resolution of the sphingolipid intermediates sphingosine 1-phosphate and ceramide 1-phosphate revealed important new insights into their tissue distribution and changes during co-infection.
Article I describes the IAV-specific oxylipin changes in the pig (german landrace) as infection model. Therefore, the sample types lung, spleen, blood plasma, and bronchoalveolar lavage from infected animals at different time points after infection were analyzed and compared with samples from uninfected pigs. Mainly in the lung and the spleen, increased amounts of certain lipid mediators were observed. These changes coincide well with already described alterations in humans and mice. Furthermore, the analysis of different sample material provided an overview about appropriate sample types. Surprisingly, many perturbations were detected in the spleen, which itself was uninfected. Based on the local reaction of lipid mediators, most studies concentrate on sample material with close contact to side of infection. Therefore, this dissertation reveals new insights into a form of systemic immune response. Besides the use of animals with a complex immune system for infection experiments, human bronchial epithelial cells (16HBE) were mono- and co-infected with the pathogens S. aureus, S. pneumoniae and IAV as described in article II. Such cells are the initial barrier for and first contact site with pathogens and thus the comprehension of this host-pathogen interaction is of essential importance. Most changes were detected during pneumococcal infection. Furthermore, the analyzed infections with bacterial pathogens differed from IAV infection by an increased synthesis of 5-hydroxyeicosatetraenoic acid (HETE). For further infections with the above mentioned pathogens, the mouse was used as an infection model. Besides infections affecting the respiratory tract, also the impact of an S. pyogenes infection in different mice strains was analyzed and described in article III. Infection-related changes in prostaglandins, which are involved in bone turnover in swollen pawns as well as enhanced amounts of sepsis- and arthritis-associated lipid mediators were detected, in case arthritis had been induced prior to infection. Furthermore, increased amounts of 20-HETE could be observed for such severe infections. An enhanced biosynthesis of 20-HETE was further confirmed in a high-pathogenic S. aureus LUG2012 infection in article IV for all examined sample types. In this last article of this dissertation, bacterial and viral infections in mice were analyzed similar to those described in article II. Mainly IAV-specific lipid mediator alterations were detected, which are in accordance with the findings of the infected pigs. The additional MALDI-MS-Imaging measurements revealed so far unknown accumulation of ceramide 1-phosphate in lung and spleen as well as enrichment in the red pulp of the spleen.
In summary, this dissertation provides substantial lipid mediator profiles for infections in three different model systems with selected bacterial and viral pathogens. The obtained data constitute a suitable basis for continuative research projects, in which the influence of single bioactive lipids on the course of infection could be examined in more detail.
Social arthropods such as termites, ants, and bees are among others the most successful animal groups on earth. However, social arthropods face an elevated risk of infections due to the dense colony structure, which facilitates pathogen transmission. An interesting hypothesis is that social arthropods are protected by chemical compounds produced by the arthropods themselves, microbial symbionts, or plants they associate with. Stegodyphus dumicola is an African social spider species, inhabiting communal silk nests. Because of the complex three-dimensional structure of the spider nest antimicrobial volatile organic compounds (VOCs) are a promising protection against pathogens, because of their ability to diffuse through air-filled pores. We analyzed the volatilomes of S. dumicola, their nests, and capture webs in three locations in Namibia and assessed their antimicrobial potential. Volatilomes were collected using polydimethylsiloxane (PDMS) tubes and analyzed using GC/Q-TOF. We showed the presence of 199 VOCs and tentatively identified 53 VOCs. More than 40% of the tentatively identified VOCs are known for their antimicrobial activity. Here, six VOCs were confirmed by analyzing pure compounds namely acetophenone, 1,3-benzothiazole, 1-decanal, 2-decanone, 1-tetradecene, and docosane and for five of these compounds the antimicrobial activity were proven. The nest and web volatilomes had many VOCs in common, whereas the spider volatilomes were more differentiated. Clear differences were identified between the volatilomes from the different sampling sites which is likely justified by differences in the microbiomes of the spiders and nests, the plants, and the different climatic conditions. The results indicate the potential relevance of the volatilomes for the ecological success of S. dumicola.
This dissertation focuses on the characterization of novel enzymes and metabolic pathways that fulfill crucial functions during marine carbohydrate degradation by Bacteroidetes and thus contributes to an advanced understanding of the global carbon cycle. Depolymerization and utilization of marine polysaccharides by Bacteroidetes requires a tremendous repertoire of enzymes with a wide range of functions. For instance, during the breakdown of the marine red algal polysaccharide porphyran, an oxidative demethylation of the methoxy sugar 6-O-methyl-D-galactose (G6Me) by cytochrome P450 monooxygenases occurs. This reaction produces huge amounts of cytotoxic formaldehyde, marine bacteria capable of degrading porphyran must therefore possess suitable formaldehyde detoxification pathways. Consequently, Article I focus on the identification of possible formaldehyde detoxification pathways in marine
Flavobacteriia, which led to the discovery of the ribulose monophosphate pathway as specific pathway for the detoxification of formaldehyde in certain Bacteroidetes like Zobellia galactanivorans. Furthermore, it was demonstrated in Article II that alcohol dehydrogenases play an essential role in the microbial utilization of G6Me and therefore possess a function in porphyran degradation. Discovering novel enzymes, entire enzymatic cascades or biotechnologically important microorganisms that can metabolize these marine carbohydrates also contributes to the utilization of marine polysaccharides as feedstock for potential biotechnological applications. A prospective biorefinery process was proposed in Article III by the identification of Bacillus licheniformis as promising utilizer of marine carbohydrate-derived monosaccharides and the creation of a microbial cell factory capable of growing on ulvan, a marine carbohydrate obtainable from algal bloom-dominating green algae, enabling an industrial use of the renewable and abundant algal biomass in future.
The focus of the first two articles was the engineering and application of enzymes for the conversion of the bio-based resources glycerol and its oxidation product glyceraldehyde for the production of the value added product glyceric acid. Article III focuses on the cloning, exploration and engineering of a polyol dehydrogenase, which later on was used as cofactor recycling system in order to produce ε-caprolactone from cyclohexanol as presented in arti-cle IV. The following paragraphs will give a short outline of each article. ARTICLE I: ASYMMETRIC SYNTHESIS OF D-GLYCERIC ACID BY AN ALDITOL OXIDASE AND DIRECTED EVOLUTION FOR ENHANCED OXIDATIVE ACTIVITY TOWARDS GLYCEROL. GERSTENBRUCH, S., WULF, H., MUßMANN, N., O’CONNELL, T., MAURER, K.-H. & BORNSCHEUER, U. T. (2012). Appl. Microbiol. Biotechnol. 96, 1243-1252. The alditol oxidase of Streptomyces coelicolor A3(2) (AldO) was used to catalyze the oxida-tion of glycerol to glyceraldehyde and glyceric acid. The enantioselectivity for the FAD-de-pendent glycerol oxidation was elucidated and different strategies were used to enhance the substrate specificity towards glycerol. Directed evolution by error-prone PCR led to an AldO double mutant with 1.5-fold improved activity for glycerol. Further improvement of activity was achieved by combination of mutations, leading to a quadruple mutant with 2.4-fold higher specific activity towards glycerol compared to the wild-type enzyme. In small-scale biotransformation concentrations up to 2.0 g•l-1 D-glyceric acid could be reached using whole cells. Investi¬gation of the effects of the introduced mutations led to a further identification of es¬sential amino acids with respect to enzyme functionality and structural stability. ARTICLE II: KINETIC RESOLUTION OF GLYCERALDEHYDE USING AN ALDEHYDE DEHYDROGENASE FROM DEINOCOCCUS GEOTHERMALIS DSM 11300 COMBINED WITH ELECTROCHEMICAL COFACTOR RECYCLING. WULF, H., PERZBORN, M., SIEVERS, G., SCHOLZ, F. & BORNSCHEUER, U. T. (2012). J. Mol. Catal. B Enzym. 74, 144-150. Two aldehyde dehydrogenases (ALDH) from Escherichia coli BL21 and Deinococcus geother-malis were cloned, characterized and evaluated according to their applicability for a bio-catalysis setup with electrolytic cofactor recycling. Both ALDHs turned out to have a sim¬ilar substrate scope and favor short to medium chain aldehydes and both oxidize glyceralde¬hyde to D-glyceric acid. The ALDH variant of D. geothermalis shows higher specific activity towards glyceraldehyde and has an elevated optimum temperature compared to the BL21 enzyme. Due to the higher specific activity of the ALDH of D. geothermalis, this enzyme was used to conduct a kinetic resolution of glyceraldehyde with electrolytic NAD+ recycling at a glassy carbon foam electrode with ABTS as redox mediator yielding in 1.8 g•l-1 glyceric acid. ARTICLE III: PROTEIN ENGINEERING OF A THERMOSTABLE POLYOL DEHYDROGENASE. WULF, H.*, MALLIN, H.*, BORNSCHEUER U.T. (2012). Enzyme Microb. Technol. 51, 217-224 (*equally contributed). The new enzyme polyol dehydrogenase PDH-11300 from D. geothermalis was extensively characterized regarding its temperature optimum and thermostability. A peptide stretch responsible for substrate recognition from the PDH-11300 was substituted by this particular stretch of a homolog enzyme, the galactitol dehydrogenase from Rhodobacter sphaeroides (PDH-158), resulting in a chimeric enzyme (PDH-loop). The substrate scopes were deter-mined and basically the chimeric enzyme represented the average of both wild-type en-zymes. A rather unexpected finding was the notably increased T5060, by 7°C to 55.3°C, and an increased specific activity against cyclohexanol. Finally, the cofactor specificity was suc¬cess-fully altered from NADH to NADPH by an Asp55Asn mutation, which is located at the NAD+ binding cleft, without influencing the catalytic properties of the dehydrogenase. ARTICLE IV: A SELF-SUFFICIENT BAEYER-VILLIGER BIOCATALYSIS SYSTEM FOR THE SYNTHESIS OF Ɛ-CAPROLACTONE FROM CYCLOHEXANOL. MALLIN, H. *, WULF, H. *, BORNSCHEUER U.T. (2013). Enzyme Microb. Technol., online, DOI: 10.1016/j.enzmictec.2013.01.007 (*equally contributed). The application of the engineered PDH-loopN mutant [1] (Article III) for the production of ε-caprolactone from cyclohexanol was investigated in a co-immobilization approach with the cyclohexanone monooxygenase from Acinetobacter calcoaceticus. Biotransformation with solubilized enzymes led to an isolated yield of 55% pure ε-caprolactone with no residual cy-clohexanol to be detected. During the immobilization experiments a higher enzyme ratio in favor of the CHMO led to higher reaction velocities. Similarly, the addition of soluble fresh CHMO during reuse of co-immobilization batches significantly increased the activity identi-fying the CHMO as the bottleneck in this reaction setup.
Amine transaminases are versatile biocatalysts for the production of pharmaceutically and agrochemically relevant chiral amines. They represent an environmentally benign alternative to waste intensive transition metal catalysed synthesis strategies, especially because of their high stereoselectivity and robustness. Therefore, they have been frequently used in the (chemo)enzymatic synthesis of amines and/or became attractive targets for enzyme engineering especially in the last decade, mainly in order to enlarge their substrate scope. Certainly, one of the most notable examples of amine transaminase engineering is the
manufacturing of the anti-diabetic drug Sitagliptin in large scale after several rounds of protein engineering. Thereby, the target amine was produced in asymmetric synthesis mode which is the most convenient and favored route to a target chiral amine, starting from the corresponding ketone. The choice of the amine donor is highly relevant for reaction design in terms of economical and thermodynamic considerations. For instance, the use of alanine as the natural amine donor is one of the most common strategies for the amination of target ketones but needs the involvement of auxiliary enzymes to shift the reaction equilibrium towards product formation. In fact, isopropylamine is probably one of the most favored donor molecules since it is cheap and achiral but it is supposed to be accepted only by a limited number of amine transaminases.
This thesis focusses on the optimization and application of amine transaminases for asymmetric synthesis reactions en route to novel target chiral amines using isopropylamine as the preferred amine donor.
Metabolomics is the scientific study of metabolites of an organism, cell, or tissue. Metabolomics makes use of different analytical approaches. In this thesis, an analytical platform consisting of proton nuclear magnetic resonance spectroscopy (1H-NMR), gas chromatography-mass spectrometry (GC-MS, EI/quadrupol) and liquid chromatography-mass spectrometry (LC-MS, ESI/TOF) was used for metabolite analysis. Due to the high physicochemical diversity of metabolites, the usage of different analytics is profitable. Focusing on metabolome analysis of microorganisms, the development of viable protocols was prerequisite. To ensure metabolome samples of best possible quality, particularly the sampling procedure has to be optimized for each microorganism to be analyzed individually. In microbial metabolomics, the energy charge value is a commonly used parameter to assure high sample quality (Atkinson 1968). The pathogenic bacterium Staphylococcus aureus and the biotechnical relevant bacterium Bacillus subtilis were main target of research. The sampling protocol development “A protocol for the investigation of the intracellular Staphylococcus aureus metabolome” (Meyer et al. 2010) and “Methodological approaches to help unravel the intracellular metabolome of Bacillus subtilis”s (Meyer et al. 2013) confirmed the need for development and verification of viable protocols. It was observed, that minor differences in the sampling procedure can cause major differences in sample quality. Using the validated analytical platform and the optimized protocols, we were able to investigate the metabolome of S. aureus and B. subtilis under different conditions. Investigations of the pathogenic bacterium S. aureus are of major interest due to its increasing resistance to antibiotics. Methicillin (multi)-resistant S. aureus (MRSA) strains are responsible for several difficult-to-treat infections. The cell wall of bacteria is the target of an array of antibiotics, like the beta-lactam antibiotics. Our study “A metabolomic view of Staphylococcus aureus and Its Ser/Thr kinase and phosphatase deletion mutants: Involvement in cell wall biosynthesis” (Liebeke et al. 2010) revealed the influence of the serine-threonine kinase on cell wall biosynthesis of S. aureus. LC-MS based metabolome data uncovered prevalent wall teichoic acid precursors in the serine-threonine kinase deletion mutant (ΔpknB), and predominantly peptidoglycan precursors in the phosphatase deletion mutant (Δstp), compared to the S. aureus wild type strain 8325. This uncovered a so far undescribed importance of the serine-threonine kinase on the cell wall metabolism and provides new insights into its regulation. The nasopharynx and the human skin are often the ecological niche of S. aureus. Furthermore, S. aureus exists outside its host, for example on catheters. Depending on its niche, S. aureus is exposed to several stress factors and limitation conditions, such as carbon source limitation and starvation. To cope with the latter, a number of regulatory cellular processes take place. In “Life and death of proteins: a case study of glucose-starved Staphylococcus aureus” (Michalik et al. 2012) protein degradation during glucose starvation was monitored. An intriguing observation was that proteins involved in branch chain amino acid biosynthesis and purine nucleotide biosynthesis were distinctly down-regulated in the clpP mutant. This lead to the assumption of a stronger repression of CodY-dependent genes in the clpP mutant. Intracellular metabolome data revealed higher GTP concentrations in the clpP mutant. This may explain the higher CodY activity and thereby stronger repression of CodY-dependent genes in the clpP mutant. Since different S. aureus strains are known to colonize different niches, global carbon source (glucose, glucose 6-phosphate, glycerol, lactate, lactose and a mixture of all) and carbon source limitation dependent exo-metabolome analyses were performed using three different S. aureus strains (HG001: laboratory strain, EN493: human endocarditis isolate and RF122: bovine mastitis strain). The most apparent observation was that RF122 can utilize lactose best, while EN493 and HG001 are better at utilizing glucose-6-phosphate compared to the bovine RF122 strain. Bacillus subtilis is an extensively studied Gram-positive and non-pathogenic bacterium. In the functional genomics approach “System-wide temporal proteomics profiling in glucose-starved Bacillus subtilis” (Otto et al. 2010) growth phase dependent changes in the proteome, transcriptome and extracellular metabolome were monitored. By mass spectrometric analysis of five different cellular subfractions, ~ 52% of the predicted proteins could be identified. To confirm and complete the proteomic data transcriptome and extracellular metabolome analyses were performed. The extracellular metabolome data ensured that cells were glucose-starved and revealed growth phase dependent metabolic footprints. In “A time resolved metabolomics study: The influence of different carbon sources during growth and starvation of Bacillus subtilis” ((Meyer et al. 2013) submitted) four different compounded cultivation media were investigated as only glucose, glucose and malate, glucose and fumarate and glucose and citrate as carbon source. It could be shown, that B. subtilis is able to maintain an intracellular metabolite homeostasis independent of the available carbon source. On the other hand, in the exo-metabolome, carbon source as well as growth phase dependent differences were detected. Furthermore, in this study the influence of ATP and GTP on the activation of the alternative RNA polymerase sigma factor B (σB) was discussed. The concentration of ATP and GTP decreased for all conditions, as cells entered the stationary growth phase. While cell growth on solely glucose and during growth on glucose and additional malate, the ATP and GTP concentrations increased slightly when the consumption of the second carbon source was initiated. Only under these conditions, a considerable σB activity increase during the transition from exponential to stationary growth phase was observed. Furthermore, the developed sampling protocol for metabolome analysis of B. subtilis enabled us to be part of a “multi omics” system biological approach to study the physiological adjustment of B. subtilis to cope with osmotic stress under chemostat conditions.
The development of the two main types of diabetes mellitus, type 1 and type 2 (T1D, T2D), is closely associated with the formation of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in insulin-secreting pancreatic β-cells. In T1D, β-cell death
is triggered by proinflammatory cytokines, which mainly lead to the formation of ROS
in mitochondria and RNS in the cytosol. Pancreatic β-cells are extraordinarily sensitive
to oxidative stress due to their low glutathione peroxidase and catalase expression.
Thus, hydrogen peroxide (H2O2) cannot be detoxified, neither sufficiently, nor rapidly.
H2O2 itself is a rather weakly reactive ROS but can react in the Fenton reaction to form
highly reactive hydroxyl radicals (●OH), that can damage cells in a variety of ways and
induce cell death. The cell and its organelles are bounded by biological membranes
that differ in their permeability to H2O2. Aquaporins (AQPs) are water-transporting
transmembrane proteins, and some isoforms have been shown to facilitate a bidirectional transport of H2O2 across cellular membranes in addition to water. The role of
AQP8 was investigated in an insulin-producing cell model by stably overexpressing
AQP8 (AQP8↑) and by a CRISPR/Cas9-mediated AQP8 knockout. However, AQP8
proved to be an essential protein for the viability of the insulin-producing RINm5F cells, and so we established a tet-on-regulated AQP8 knockdown (AQP8 KD). Our results highlight that AQP8 is involved in H2O2 transport across the plasma and mitochondrial membranes, and that AQP8 expression gets upregulated by proinflammatory cytokines (in vitro) and in an acutely diabetic rat model (in vivo). Furthermore, it was shown that the increased proinflammatory cytokine toxicity is due to enhanced mitochondrial oxidative stress, because H2O2 cannot be efficiently transported in AQP8 KD cells and ●OH
are increasingly generated. Caspase activity then raises, and apoptosis is increasingly
induced coupled with a proportion of ferroptosis-mediated cell death because of a concomitant decrease in nitric oxide (NO●) concentration. In conclusion, AQP8 is localized in the plasma and mitochondrial membrane of insulin-producing RINm5F cells, where it is involved in H2O2 transport. In T1D, AQP8 plays an important role in the transport of H2O2 from the mitochondrial matrix to the cytosol so that the concentration is lowered in the mitochondria. This wider distribution of H2O2 may ease the inactivation of H2O2.
Abstract
Aim
To examine the associations between bone turnover markers and periodontitis in two cross‐sectional population‐based studies.
Materials and Methods
We used data from two independent adult samples (N = 4993), collected within the Study of Health in Pomerania project, to analyse cross‐sectional associations of N‐procollagen type 1 amino‐terminal propeptide (P1NP), C‐terminal cross‐linking telopeptide, osteocalcin, bone‐specific alkaline phosphatase (BAP), fibroblast growth factor 23, wingless‐type mouse mammary tumour virus integration site family member 5a (WNT5A), and sclerostin values with periodontitis. Confounder‐adjusted gamma and fractional response regression models were applied.
Results
Positive associations were found for P1NP with mean pocket probing depth (PPD; eβ=1.008; 95% confidence interval [CI]: 1.001–1.015), mean clinical attachment loss (mean CAL; eβ=1.027; 95% CI: 1.011–1.044), and proportion of sites with bleeding on probing (%BOP; eβ=1.055; 95% CI: 1.005–1.109). Similar associations were seen for BAP with %BOP (eβ=1.121; 95% CI: 1.042–1.205), proportion of sites with PPD ≥4 mm (%PPD4) (eβ=1.080; 95% CI: 1.005–1.161), and sclerostin with %BOP (eβ=1.308; 95% CI: 1.005–1.704). WNT5A was inversely associated with mean PPD (eβ=0.956; 95% CI: 0.920–0.993) and %PPD4 (eβ=0.794; 95% CI: 0.642–0.982).
Conclusions
This study revealed scattered associations of P1NP, BAP, WNT5A, and sclerostin with periodontitis, but the results are contradictory in the overall context. Associations reported in previous studies could not be confirmed.
Diese Arbeit beschreibt den Aufbau eines Assays zur Selektion eines Ribozyms, welches die Desaminierung von Adenosin zu Inosin katalysiert. Diese Reaktion spielt im Organismus, wo sie proteinkatalysiert abläuft, eine wichtige Rolle (Nukleotidmetabolismus, RNA-Editing). Zusätzlich besitzt ein solches Ribozym das Potenzial zur gezielten Veränderung von RNA-Sequenzen. Das Projekt hat somit evolutionstheoretische (RNA-Welt-Hypothese) als auch gentherapeutische Relevanz. Zentraler Punkt des vorgestellten Assays ist die Markierung einer Mischung verschiedener RNA-Sequenzen (= Bibliothek) mit dem Substrat Adenosin. Dieses trägt an der exozyklischen Aminogruppe eine Biotinfunktion. Wird diese Bibliothek auf einer festen Phase über die Biotin/Streptavidin-Wechselwirkung immobilisiert und den Selektionsbedingungen unterworfen, werden Spezies mit der gewünschten Aktivität in Lösung entlassen. Diese können eluiert und über RT-PCR angereichert werden. Die Funktionalisierung der RNA-Bibliothek geschieht am 5’-Ende jeder Sequenz durch Transkriptionspriming aus einer chemisch synthetisierten DNA-Bibliothek in Gegenwart der vier NTPs und eines Guanosin-5’-monophosphatderivats, dem „Initiator“. Letzteres ist über die 5’-Phosphatfunktion mit dem biotinylierten Substrat Adenosin verknüpft. Das Initiatormolekül wurde in zwei Strategien synthetisiert. Die erste Strategie fand an der festen Phase unter Verwendung des Phosphoramiditverfahrens statt und lieferte Initiator in nanomolarem Maßstab. Die zweite Strategie bestand aus einer 17-stufigen Synthese in Lösung und ergab fast identisches Initiatormolekül in µmolarem Maßstab. Beide Initiatormoleküle wurden erfolgreich zur Funktionalisierung einer RNA eingesetzt. Zur qualitativen Dokumentation des Einbaus des Initiators wurde eine auf Chemilumineszenzdetektion basierende Methode entwickelt. Dabei wurden die Transkriptionsprodukte auf eine Nylonmembran immobilisiert und mit einem Fusionsprotein aus Alkalischer Phosphatase und Streptavidin inkubiert, welches spezifisch den Biotinrest bindet. Durch Zugabe eines möglichen Substrats der Alkalischen Phosphatase wird ein Chemilumineszenzsignal erzeugt, was über einen Röntgenfilm dokumentiert wurde. Dieser qualitative Nachweis wurde erweitert, um die Einbaueffizienz zu quantifizieren. Dazu wurde eine RNA, welche zu 100% mit dem Initiatormolekül markiert war, mit Hilfe des Phosphoramiditverfahrens hergestellt. Diese als Standard fungierende RNA wurde in definierter Menge zusammen mit definierten Mengen an statistisch funktionalisierten Primingprodukt geblottet. Die Quantifizierung der Chemilumineszenz der Proben erfolgte mit Hilfe eines Photosystems und durch Integration der Signalintensitäten. Dadurch konnte der Anteil der in den durchgeführten Primingreaktionen mit Initiator markierten RNA zu maximal 3 % bestimmt werden. Obwohl eine Erhöhung dieses Wertes z.B. durch Optimierung der Initiatorstruktur wünschenswert ist, ist damit die Funktionalisierung einer RNA-Bibliothek in einer für die Selektion ausreichenden Menge durchaus möglich. Zur Evaluation des Assays wurde der Selektionsschritt simuliert, in welchem ein über das Initiatormolekül festphasengebundenes Ribozym spezifisch zur Selbstspaltung aktiviert wird. Zu diesem Zweck wurden ein Hammerheadriboyzm, ein Hairpinribozym sowie ein DNAzym untersucht. Dabei wurde festgestellt, dass die Spaltaktivität aller drei Systeme durch Funktionalisierung mit dem Initiator in Lösung fast vollständig inhibiert wird, unmarkierte Spezies unter identischen Bedingungen jedoch uneingeschränkte Spaltaktivität zeigen. Die beobachtete Inhibierung beruht auf einem intramolekularen Effekt, der möglicherweise zu einer Verschiebung des Konformerengleichgewichts der Testsysteme hin zu spaltinaktiven Konformeren führt. Zusätzlich wurde die Spaltaktivität des mit Initiator markierten und an einer Festphase immobilisierten Hairpinribozyms untersucht. Auch hier war eine stark verringerte Spaltaktivität zu beobachten, welche jedoch in unspezifischen Wechselwirkungen zwischen Festphase und Ribozym begründet liegen könnten. Die verwendeten Systeme eignen sich offenbar nicht zur Evaluierung des Assays, was jedoch die Möglichkeit offen lässt, dass im geplanten Assay selektierte RNA-Sequenzen die Funktionalisierung mit Initiator tolerieren. Die Ergebnisse dieser Arbeit erlauben den Schluss, dass die gewählte Strategie zur Selektion der Adenosindesaminase einige Punkte beinhaltet, welche nach Möglichkeit optimiert werden müssen, um eine effizientere Selektion durchführen zu können. Prinzipiell ist die Vorraussetzung für die Selektion der Adenosindesaminase durch die beschriebene Methode jedoch geschaffen und kann basierend auf den vorgestellten Ergebnissen in zukünftigen Studien durchgeführt werden.
Azide‐Modified Nucleosides as Versatile Tools for Bioorthogonal Labeling and Functionalization
(2022)
Abstract
Azide‐modified nucleosides are important building blocks for RNA and DNA functionalization by click chemistry based on azide‐alkyne cycloaddition. This has put demand on synthetic chemistry to develop approaches for the preparation of azide‐modified nucleoside derivatives. We review here the available methods for the synthesis of various nucleosides decorated with azido groups at the sugar residue or nucleobase, their incorporation into oligonucleotides and cellular RNAs, and their application in azide‐alkyne cycloadditions for labelling and functionalization.
In this thesis, all three BVMOs from Pseudomonas putida NCIMB10007, that were known to be responsible for the ability of this strain to degrade camphor since the 1950s were successfully made available as recombinant biocatalysts. While the genomic sequence of 2,5-DKCMO was available from the database, the genes encoding 3,6-DKCMO and OTEMO had to be identified using certain PCR-techniques first. All three enzymes were cloned into standard plasmids enabling convenient expression in E. coli facilitating the application of the enzymes in organic chemistry. Their synthetic potential was already reported during the 1990s, but at that time their efficient application was limited due to difficulties with respect to low production levels and insufficient purity and separation of enzyme fractions. These drawbacks are now overcome. Furthermore, biochemical characterization of the camphor-degrading BVMOs was performed including the substrate spectra of these enzymes. Thereby OTEMO turned out not only to have a broad substrate scope accepting mono- and bicyclic aliphatic and arylaliphatic ketones, but also to efficiently convert alpha/beta-unsaturated cycloalkanones due to the similarity of these compounds to OTEMOs natural substrate. Finally, the major limitation in the synthetic application of Type II BVMOs was addressed by searching a flavin-reductase suitable for coupling to these two-component oxygenases. Putative candidates from the respective P. putida strain were identified by the use of amino acid motifs conserved in other representatives of two-component systems. While these enzymes failed, flavin-reductase Fre from E. coli - that also contained the motifs - was shown to enhance the activity of the DKCMOs when applied as crude cell extract as well as pure enzyme. This finding represents a key step for future application of Type II BVMOs.
In teaching electrochemistry, it is of primary importance to make students always aware of the relations between electrochemistry and all the non-electrochemical topics, which are taught. The vast majority of students will not specialise in electrochemistry, but they all can very much benefit from the basics and concepts of electrochemistry. This paper is aimed to give suggestions how the teaching of electrochemistry can easily be interrelated to topics of inorganic, organic, analytical, environmental chemistry, biochemistry and biotechnology.
Introduction
Respiratory tract infections are a worldwide health problem for humans and animals. Different cell types produce lipid mediators in response to infections, which consist of eicosanoids like hydroxyeicosatetraenoic acids (HETEs) or oxylipins like hydroxydocosahexaenoic acids (HDHAs). Both substance classes possess immunomodulatory functions. However, little is known about their role in respiratory infections.
Objectives
Here, we aimed to analyze the lipid mediator imprint of different organs of C57BL/6J mice after intranasal mono-infections with Streptococcus pneumoniae (pneumococcus), Staphylococcus aureus or Influenza A virus (IAV) as wells as pneumococcal-IAV co-infection.
Methods
C57BL/6J mice were infected with different pathogens and lungs, spleen, and plasma were collected. Lipid mediators were analyzed using HPLC-MS/MS. In addition, spatial-distribution of sphingosine 1-phosphate (S1P) and ceramide 1-phosphates (C1P) in tissue samples was examined using MALDI-MS-Imaging. The presence of bacterial pathogens in the lung was confirmed via immunofluorescence staining.
Results
We found IAV specific changes for different HDHAs and HETEs in mouse lungs as well as enhanced levels of 20-HETE in severe S. aureus infection. Moreover, MALDI-MS-Imaging analysis showed an accumulation of C1P and a decrease of S1P during co-infection in lung and spleen. Long chain C1P was enriched in the red and not in the white pulp of the spleen.
Conclusions
Lipid mediator analysis showed that host synthesis of bioactive lipids is in part specific for a certain pathogen, in particular for IAV infection. Furthermore, MS-Imaging displayed great potential to study infections and revealed changes of S1P and C1P in lungs and spleen of co-infected animals, which was not described before.
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.
This thesis focuses on the establishment of biocatalytic cascade reactions for the production and detection of industrially relevant flavor and fragrance compounds for food and cosmetic products. To meet the consumer’s demand for those products to be natural, environmentally friendly biocatalytic manufacturing processes that operate GMO-free must be established. Thus, this thesis presents such pathways for the production of an industrially relevant long-chain hydroxy fatty acid and the important flavor and aroma compound raspberry ketone. Furthermore, a biosensor for aldehyde detection was implemented to facilitate screening for suitable biocatalysts that produce industrially relevant aldehydes that are widely applied in the flavor and fragrance industry.
Biocatalytic Production of Amino Carbohydrates through Oxidoreductase and Transaminase Cascades
(2019)
Plant-derived carbohydrates are an abundant renewable re- source. Transformation of carbohydrates into new products, in- cluding amine-functionalized building blocks for biomaterials applications, can lower reliance on fossil resources. Herein, bio- catalytic production routes to amino carbohydrates, including oligosaccharides, are demonstrated. In each case, two-step bio- catalysis was performed to functionalize d-galactose-contain- ing carbohydrates by employing the galactose oxidase from Fusarium graminearum or a pyranose dehydrogenase from
Agaricus bisporus followed by the w-transaminase from Chro- mobacterium violaceum (Cvi-w-TA). Formation of 6-amino-6- deoxy-d-galactose, 2-amino-2-deoxy-d-galactose, and 2-amino- 2-deoxy-6-aldo-d-galactose was confirmed by mass spectrome- try. The activity of Cvi-w-TA was highest towards 6-aldo-d-gal- actose, for which the highest yield of 6-amino-6-deoxy-d-galac- tose (67%) was achieved in reactions permitting simultaneous oxidation of d-galactose and transamination of the resulting 6- aldo-d-galactose.
This thesis investigates the biocatalytic synthesis of amines and amino alcohols. The applicability and economic feasibility of biocatalysis for chiral amine synthesis is reviewed and the findings were compared to established chemical processes using relevant process parameters (TON, TOF and STY). This review clearly showcases the potential of biocatalysis for the synthesis of chiral amines and provides a valuable guide for synthetic chemists who want to benefit from these new opportunities. Next, biocatalysis is applied for the synthesis of an amino alcohol with two stereocentres: A novel route for the synthesis of all four stereoisomers of 4-amino-1-phenylpentane-2-ol is presented. Enzymes were applied to install both stereocentres successively, which allowed the selective synthesis with high yields and optical purities. A small scale preparative asymmetric transamination yielded one amino alcohol stereoisomer selectively. The approach presented in this thesis provides a valuable option for the synthesis of this compound class as it is highly selective, step efficient and circumvents the need for protecting groups as well as transition-metal catalysis. The substrate scope of an (S)-selective amine transaminase (ATA) was altered in order to expand the applicability for amino alcohol synthesis. Protein engineering was conducted to enlarge the small binding pocket. Small scale preparative synthesis of the 1,2-amino alcohol (R)-phenylglycinol exemplifies the applicability of the evolved variants for the asymmetric synthesis of this compound. The designed variants expand the collection of ATAs that are suitable for the synthesis of amino alcohols with bulkier substituents. To deepen the understanding of ATAs further, a class III TA family wide analysis (which includes (S)-selective ATAs) is presented. After comparing the active site architectures and performing literature research amino acids were identified that correlate with the reaction- and substrate specificity of the enzymes within this family. This information is compiled in a sequence-function matrix, which allows the prediction of the main activity of biochemically uncharacterised enzymes from their sequence. These insights provide a better understanding of the activity determining residues in (S)-ATAs and class III TAs in general.
β-Glucosidases (Bgls) convert cellobiose and other soluble cello-oligomers into glucose and play important roles in fundamental biological processes, providing energy sources in living organisms. Bgls are essential terminal enzymes of cellulose degradation systems and attractive targets for lignocellulose-based biotechnological applications. Characterization of novel Bgls is important for broadening our knowledge of this enzyme class and can provide insights into its further applications. In this study, we report the biochemical and structural analysis of a Bgl from the hemicellulose-degrading thermophilic anaerobe Thermoanaerobacterium saccharolyticum (TsaBgl). TsaBgl exhibited its maximum hydrolase activity on p-nitrophenyl-β-d-glucopyranoside at pH 6.0 and 55 °C. The crystal structure of TsaBgl showed a single (β/α)8 TIM-barrel fold, and a β8-α14 loop, which is located around the substrate-binding pocket entrance, showing a unique conformation compared with other structurally known Bgls. A Tris molecule inhibited enzyme activity and was bound to the active site of TsaBgl coordinated by the catalytic residues Glu163 (proton donor) and Glu351 (nucleophile). Titration experiments showed that TsaBgl belongs to the glucose-tolerant Bgl family. The gatekeeper site of TsaBgl is similar to those of other glucose-tolerant Bgls, whereas Trp323 and Leu170, which are involved in glucose tolerance, show a unique configuration. Our results therefore improve our knowledge about the Tris-mediated inhibition and glucose tolerance of Bgl family members, which is essential for their industrial application.
Free radicals are known to induce significant structural and functional modifications to the cell membrane and its components. Biophysical quantification of such changes using single molecule studies highlight the role of these individual biomolecules. In this PhD work, we focus on nitric oxide radical and try to understand how they influence interaction of different biomolecules with lipid membranes by using biomimetic systems. In specific we try to answer how cell membrane permeability and bilayer thickness would be influenced by the nitric oxide radical with different phospholipids compositions (i.e. on planar supported lipid bilayers). Later we tested, interaction of transmembrane protein integrin αiibβ3 incorporated into the bilayer (i.e. nanodiscs) with nitric oxide. Finally, how to overcome the negative effects encountered by the phospholipids and proteins using biopolymer coated gold nanoparticles as delivery system. The study involved use of atomic force microscopy and quartz-crystal microbalance with dissipation as primary investigation tools complemented with other relevant biophysical and biochemical techniques.
Neben verschiedenen gesundheitsfördernden Eigenschaften hat das Flavonoid Phloretin eine süßkraftverstärkende Wirkung. Es ist nicht nur in der Pharma- und Kosmetikindustrie, sondern auch als Aromastoff für die Lebensmittelproduktion von Interesse. Bislang gab es kein vielversprechendes, biotechnologisches System zur Herstellung von Phloretin. Die Extraktion aus Pflanzen führt aufgrund niedriger und schwankender Konzentrationen zu einer schlechten Verfügbarkeit. Chemisch synthetisiertes Phloretin hingegen kann aufgrund der „Europäischen Aromenverordnung“ nicht als „natürlicher Aromastoff“ deklariert werden. Daher ist Phloretin als „natürlicher Aromastoff“ relativ teuer und für die Aromenindustrie kaum nutzbar. Ziel dieser Arbeit war es, einen effizienten Weg zur biotechnologischen Produktion von Phloretin zu finden. Als Substrat sollte bevorzugt Naringenin eingesetzt werden. Obwohl ähnliche Reaktionswege in der Literatur beschrieben wurden, konnte mit ausgewählten filamentösen Pilzen in Ganzzellbiokatalysen keine Phloretinbildung beobachtet werden. Es gibt jedoch auch Bakterien, die in der Lage sind, die Zielreaktion auszuführen. Da es sich hierbei ausschließlich um obligate Anaerobier handelt, eignen sich diese Stämme kaum für die biotechnologische Produktion von Phloretin. Außerdem erfolgt in diesen Bakterien die Zielreaktion als Teil des Naringeninabbaus, das entstehende Phloretin wird abgebaut. Über die Zielreaktion im anaeroben Bakterium Eubacterium ramulus lagen bereits Informationen aus anderen Forschungsarbeiten vor, darunter auch ein Sequenzfragment vom N-Terminus der Chalconisomerase (CHI). Die CHI katalysiert die Isomerisierung von Naringenin zu Naringeninchalcon. Aus der Literatur ging hervor, dass E. ramulus die Zielreaktion von Naringenin über Naringeninchalcon zum Phloretin durchführen kann, aber dass außer der CHI ein weiteres Enzym beteiligt ist. Das genetische Potential von E. ramulus sollte genutzt werden, um einen rekombinanten Mikroorganismus zu generieren. Nach der Sequenzierung des Genoms von E. ramulus konnte die N-terminale Sequenz in der vorliegenden Arbeit genutzt werden, um in silico das Gen der CHI zu identifizieren. Da vermutet wurde, dass für die Reduktion von Naringeninchalcon zu Phloretin eine Enoatreduktase (ERED) verantwortlich ist, wurde über eine BLAST-Analyse ein konserviertes Motiv für Enoatreduktasen ermittelt, mit dem im Genom von E. ramulus das Gen einer ERED in silico identifiziert wurde. Die Gene wurden anschließend in E. coli kloniert. Für die CHI konnte eine sehr gute Überexpression und enzymatische Aktivität in zellfreien Biokatalysen nachgewiesen werden. Der Aktivitätsnachweis ermöglichte auch die Aufreinigung der CHI aus dem Proteinrohextrakt. In der Diplomarbeit von M. Thomsen wurde die Aufreinigung optimiert. Der Aufreinigungsprozess beinhaltete eine Anionenaustauschchromatographie, hydrophobe Interaktionschromatographie und Gelfiltration und führte zu einer sehr hohen Reinheit der CHI. Das aufgereinigte Enzym wurde anschließend biochemisch charakterisiert. Außerdem wurden mit dem rekombinanten Stamm (mit Genen für CHI und ERED) Versuche im Ganzzellsystem mit Naringenin durchgeführt. Dabei wurde festgestellt, dass die Reaktion zum Zielprodukt Phloretin empfindlich gegenüber Sauerstoff ist. Unter anaerober Atmosphäre konnte in diesem System eine höhere Phloretinbildung beobachtet werden. Da die CHI in vorherigen Untersuchungen keine Sensitivität gegenüber Sauerstoff gezeigt hatte, wurden in der Diplomarbeit von C. Peters Expression und Aktivität der ERED unter diesem Aspekt näher untersucht. Es konnte festgestellt werden, dass die Expression der ERED unter anaeroben Bedingungen erfolgen sollte, das Enzym ist jedoch auch unter Anwesenheit von Sauerstoff aktiv. Die in der Literatur beschriebenen Ansätze zur Entwicklung von biotechnologischen Verfahren zur Phloretinproduktion basieren vor allem auf dem Einsatz pflanzlicher Gene und führten bisher nur zu geringen Produktkonzentrationen. In der vorliegenden Arbeit ist es gelungen, ein neues System zur biotechnologischen Produktion von Phloretin zu entwickeln, mit dem eine höhere Ausbeute erzielt werden kann. Basierend auf den neu identifizierten Genen aus E. ramulus, die erfolgreich in E. coli exprimiert wurden, wird das Problem der rekombinanten Expression eukaryotischer Gene in Prokaryoten umgangen. Im Vergleich zu E. ramulus ist E. coli in der Biotechnologie bereits etabliert und relativ unempfindlich gegenüber Sauerstoff. Außerdem findet der Phloretinabbau, wie er in E. ramulus und in verwandten Bakterien ablaufen würde, in E. coli nicht statt. In dieser Arbeit wurde gezeigt, dass es für die Weiterentwicklung der industriellen Biotechnologie vorteilhaft ist, das enorme Potential des bakteriellen Stoffwechsels durch Gentechnik nutzbar zu machen. Durch diese Strategie wird „nachhaltige Biokatalyse auf neuen Wegen“ in der Flavonoidbiotechnologie ermöglicht.
The hairpin ribozyme is a small Mg2+-dependent catalytic RNA molecule able to catalyze the trans-cleavage of an RNA substrate via a reversible trans-esterification mechanism. In this study, the cleavage activities of several fragmented hairpin ribozyme systems were examined. Due to the complex catalytic structure of the hairpin ribozyme, a new boronic acid ester was used as a covalent linkage to hold the folding of the functional system. It has been demonstrated the possibility of replacing the phosphodiester linkage, at specific positions, with a boronic acid ester to restore or improve the catalytic activity of fragmented hairpin ribozyme.
Boronate esters formed by reaction of an oligonucleotide carrying a 5′-boronic acid moiety with the 3′-terminal cis-diol of another have been shown previously to assist assembly of fragmented DNAzymes. Here we demonstrate that boronate esters replacing the natural phosphodiester linkage at selected sites of two functional RNAs, the hairpin ribozyme and the Mango aptamer, allow assembly of functional structures. The hairpin ribozyme, a small naturally occurring RNA that supports the reversible cleavage of appropriate RNA substrates, is very sensitive to fragmentation. Splitting the ribozyme at four different sites led to a significant decrease or even loss of cleavage and ligation activity. Ribozymes assembled from fragments capable of boronate ester formation showed restoration of cleavage activity in some but not all cases, dependent on the split site. Ligation proved to be more challenging, no supportive effect of the boronate ester was observed. Split variants of the Mango aptamer also showed a dramatic loss of functionality, which however, was restored when 5′-boronic acid modified fragments were used for assembly. These studies show for the first time that boronate esters as internucleoside linkages can act as surrogates of natural phosphodiesters in functional RNA molecules.
Abstract
The 10–23 DNAzyme is an artificially developed Mg2+‐dependent catalytic oligonucleotide that can cleave an RNA substrate in a sequence‐specific fashion. In this study, new split 10–23 DNAzymes made of two nonfunctional fragments, one of which carries a boronic acid group at its 5′ end, while the other has a ribonucleotide at its 3′ end, were designed. Herein it is demonstrated that the addition of Mg2+ ions leads to assembly of the fragments, which in turn induces the formation of a new boronate internucleoside linkage that restores the DNAzyme activity. A systematic evaluation identified the best‐performing system. The results highlight key features for efficient control of DNAzyme activity through the formation of boronate linkages.
Herein, a new type of carbodicarbene (CDC) comprising two different classes of carbenes is reported; NHC and CAAC as donor substituents and compare the molecular structure and coordination to Au(I)Cl to those of NHC‐only and CAAC‐only analogues. The conjugate acids of these three CDCs exhibit notable redox properties. Their reactions with [NO][SbF6] were investigated. The reduction of the conjugate acid of CAAC‐only based CDC with KC8 results in the formation of hydrogen abstracted/eliminated products, which proceed through a neutral radical intermediate, detected by EPR spectroscopy. In contrast, the reduction of conjugate acids of NHC‐only and NHC/CAAC based CDCs led to intermolecular reductive (reversible) carbon–carbon sigma bond formation. The resulting relatively elongated carbon–carbon sigma bonds were found to be readily oxidized. They were, thus, demonstrated to be potent reducing agents, underlining their potential utility as organic electron donors and n‐dopants in organic semiconductor molecules.
This study investigated, if a mixed electroactive bacterial (EAB) culture cultivated heterotrophically at a positive applied potential could be adapted from oxidative to reductive or bidirectional extracellular electron transfer (EET). To this end, a periodic potential reversal regime between − 0.5 and 0.2 V vs. Ag/AgCl was applied. This yielded biofilm detachment and mediated electroautotrophic EET in combination with carbonate, i.e., dissolved CO2, as the sole carbon source, whereby the emerged mixed culture (S1) contained previously unknown EAB. Using acetate (S2) as well as a mixture of acetate and carbonate (S3) as the main carbon sources yielded primarily alternating electrogenic organoheterotropic metabolism with the higher maximum oxidation current densities recorded for mixed carbon media, exceeding on average 1 mA cm−2. More frequent periodic polarization reversal resulted in the increase of maximum oxidative current densities by about 50% for S2-BES and 80% for S3-BES, in comparison to half-batch polarization. The EAB mixed cultures developed accordingly, with S1 represented by mostly aerobes (84.8%) and being very different in composition to S2 and S3, dominated by anaerobes (96.9 and 96.5%, respectively). S2 and S3 biofilms remained attached to the electrodes. There was only minor evidence of fully reversible bidirectional EET. In conclusion the three triplicates fed with organic and/or inorganic carbon sources demonstrated two forms of diauxie: Firstly, S1-BES showed a preference for the electrode as the electron donor via mediated EET. Secondly, S2-BES and S3-BES showed a preference for acetate as electron donor and c-source, as long as this was available, switching to CO2 reduction, when acetate was depleted.
This thesis deals with the characterisation and engineering of new thermophilic PET hydrolases as potential candidates for an eco-friendly biocatalytic recycling approach for the upcycling or downcycling of polyethylene terephthalate (PET) on industrial scale. Furthermore, high-throughput screening methods are described that detect the products of PET hydrolysis. The high demand of PET in the packaging and textile industries with a global production of 82 million metric tons per year has significantly contributed to the global solid waste stream and environmental plastic pollution after its end-of-life. Although PET hydrolases have been identified in various microorganisms, only a handful of benchmark enzymes have been engineered for industrial applications. Therefore, the identification of new PET hydrolases from metagenomes or via protein engineering approaches, especially thermophilic PET hydrolases with optimal operating temperatures (i.e., increased thermostability and activity) near the glass transition temperature of the polymer PET, is a crucial step towards a bio-based circular plastic economy. Article I demonstrates that metagenome-derived thermophilic PET hydrolases can be significantly improved using different engineering approaches to achieve a similar activity level as the well-established leaf-branch-compost cutinase (LCC) F243I/D238C/S283C/Y127G variant (LCC ICCG). In Article II, thermostable variants of a mesophilic enzyme (PETase from Ideonella sakaiensis) were identified from a mutant library and characterised against PET substrates in various forms. Articles III and IV describe the application of high-throughput methods for the identification of novel PET hydrolases by directly assaying terephthalic acid (TPA), one of the monomeric building blocks of PET. Furthermore, Article IV describes the possibility of a one-pot conversion of the TPA-based aldehydes produced to their diamines as example for an open-loop upcycling method.
Characterization of proteins from the 3N5M family reveals an operationally stable amine transaminase
(2022)
Amine transaminases (ATA) convert ketones into optically active amines and are used to prepare active pharmaceutical ingredients and building blocks. Novel ATA can be identified in protein databases due to the extensive knowledge of sequence-function relationships. However, predicting thermo- and operational stability from the amino acid sequence is a persisting challenge and a vital step towards identifying efficient ATA biocatalysts for industrial applications. In this study, we performed a database mining and characterized selected putative enzymes of the β-alanine:pyruvate transaminase cluster (3N5M) — a subfamily with so far only a few described members, whose tetrameric structure was suggested to positively affect operational stability. Four putative transaminases (TA-1: Bilophilia wadsworthia, TA-5: Halomonas elongata, TA-9: Burkholderia cepacia, and TA-10: Burkholderia multivorans) were obtained in a soluble form as tetramers in E. coli. During comparison of these tetrameric with known dimeric transaminases we found that indeed novel ATA with high operational stabilities can be identified in this protein subfamily, but we also found exceptions to the hypothesized correlation that a tetrameric assembly leads to increased stability. The discovered ATA from Burkholderia multivorans features a broad substrate specificity, including isopropylamine acceptance, is highly active (6 U/mg) in the conversion of 1-phenylethylamine with pyruvate and shows a thermostability of up to 70 °C under both, storage and operating conditions. In addition, 50% (v/v) of isopropanol or DMSO can be employed as co-solvents without a destabilizing effect on the enzyme during an incubation time of 16 h at 30 °C.
Charakterisierung der Expression und Funktion metabolischer Enzyme im humanen intestinalen Gewebe
(2019)
Bei der Arzneimittelentwicklung liegt der Fokus nicht nur auf der Wirksamkeit und Sicherheit einer pharmakologisch aktiven Substanz, sondern auch auf einer möglichst einfachen, idealerweise oralen Applikation. Um die benötigten Wirkstoffkonzentrationen im Zielorgan zu erreichen, wird die einzunehmende Dosis eines Medikaments in Abhängigkeit der präsystemischen Elimination ermittelt. Inzwischen ist bekannt, dass nicht ausschließlich der hepatische, sondern auch der intestinale Stoffwechsel die orale Bioverfügbarkeit eines Medikaments wesentlich beeinflussen kann. Arzneistoffe, die während der Darmpassage einer starken Metabolisierung unterliegen, sind zudem prädestiniert für unerwünschte Interaktionen mit anderen Substanzen, welche die entsprechenden Stoffwechselenzyme hemmen oder induzieren. Für die Abschätzung pharmakokinetischer Parameter eines neuen Wirkstoffs sind daher Kenntnisse zur Expression sowie Funktion klinisch relevanter intestinaler Stoffwechselenzyme von Bedeutung.
Bisher publizierte Daten basieren größtenteils auf der Genexpression, obwohl aufgrund posttranskriptionaler Prozesse nicht zwingend Aussagen zur resultierenden Proteinmenge getroffen werden können. Die verfügbaren Daten zum intestinalen Proteingehalt wurden mittels immunologischer Methoden erhoben, die erhebliche Limitationen in Bezug auf Spezifität, Reproduzierbarkeit und Robustheit aufweisen. Diese Aspekte finden bei den inzwischen etablierten LC-MS/MS-basierten Targeted-Proteomics-Methoden Berücksichtigung. Dazu werden die Proteine einer Messprobe enzymatisch gespalten, um entstehende proteospezifische Peptide zur Quantifizierung der Proteine von Interesse zu nutzen.
Ein Ziel der vorliegenden Arbeit bestand in der Entwicklung und Validierung einer entsprechenden Methode zur gleichzeitigen Bestimmung von CYP1A2, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6, CYP2E1, CYP3A4, CYP3A5, UGT1A1, UGT1A3, UGT2B7 sowie UGT2B15 in biologischen Matrices, welche die aktuell gültigen Leitlinien in Bezug auf Selektivität, Linearität, Richtigkeit, Präzision und Stabilität erfüllt. Bereits bei der ersten Anwendung der Methode zur Quantifizierung der Enzyme in kommerziell erhältlichen und selbst isolierten Mikrosomen zeigte sich, welchen erheblichen Einfluss die Probenvorbereitung auf die ermittelten Proteingehalte hat.
Diese Erkenntnis wurde im Rahmen eines internationalen Projektes bestätigt, bei dem humane Leberproben desselben Ursprungs in diversen Laboren mit den dort etablierten Methoden prozessiert worden sind. Bezogen auf die eingesetzte Gewebemenge ergaben sich bei der Messung der Mikrosomen 6 - 30-fach geringere Enzymgehalte als bei der Analyse des nicht-fraktionierten Gewebes, da die subzelluläre Aufspaltung einer Probe mit erheblichen Proteinverlusten einhergeht. Folglich wurden alle weiteren Untersuchungen zur absoluten Enzymquantifizierung unter Verwendung von filterbasierten Zentrifugaleinheiten (filter aided sample preparation; FASP) mit Gesamtgewebelysatproben durchgeführt. Sowohl die optimierte Probenaufarbeitung als auch die validierte Targeted-Proteomics-Methode fanden bei der Untersuchung der Darmsegmente von 9 Spendern Anwendung, wobei jeweils Gewebe aus dem Duodenum, oberen und unteren Jejunum, Ileum sowie Colon zur Verfügung stand. Von den 13 untersuchten Enzymen wurden in allen Dünndarmabschnitten nur CYP2C9, CYP2C19, CYP2D6, CYP3A4, CYP3A5, UGT1A1, UGT1A3 und UGT2B7 nachgewiesen, deren Gehalt im Jejunum am höchsten war. Im Colon wurde auf Proteinebene keines der Metabolisierungsenzyme detektiert. Die entsprechenden Genexpressionsdaten dieser 8 Enzyme korrelieren signifikant mit den ermittelten Proteinwerten. Korrespondierend zur fehlenden Nachweisbarkeit der übrigen 5 Enzyme auf Proteinebene waren die Gene CYP2B6, CYP2C8, CYP2E1 sowie UGT2B15 nur sehr geringfügig und CYP1A2 gar nicht exprimiert.
Zur Charakterisierung der metabolischen Aktivität der intestinalen Enzyme wurde eine weitere LC-MS/MS-basierte Methode entwickelt und validiert. Als Modellsubstrate fungierten Diclofenac (CYP2C9), Omeprazol (CYP2C19), Dextromethorphan (CYP2D6), Midazolam (CYP3A), Ezetimib (UGT1A) und Naloxon (UGT2B7). Die begrenzte Verfügbarkeit des intestinalen Gewebes sowie dessen sehr geringer mikrosomaler Proteingehalt stellten besondere Anforderungen an die Sensitivität der Methode. Ihre Eignung zur Charakterisierung der intestinalen Metabolisierungsaktivität wurde bei der Anwendung auf ein jejunales Mikrosomen-Gemisch gezeigt.
Die im Rahmen dieser Arbeit generierten Daten zur Expression klinisch bedeutsamer Metabolisierungsenzyme entlang des humanen Darms tragen zu einem besseren Verständnis des intestinalen First-Pass-Metabolismus bei. Diese Kenntnisse können sowohl bei der Entwicklung neuer Arzneistoffe als auch für die Erstellung von Physiologie-basierten pharmakokinetischen Modellen (PBPK-Modellen) nützlich sein, um die orale Bioverfügbarkeit sowie das Interaktionspotential pharmakologisch aktiver Substanzen abzuschätzen.
Das klarzellige Nierenzellkarzinom (ccRCC) ist eine von vielen Krebserkrankungen. Viele Patienten weisen eine Mutation im Von-Hippel-Lindau-Gen (VHL) auf und/ oder zeigen eine Überexpression des Enzyms Nicotinamid-N-Metyltransferase (NNMT).
Es wurden insgesamt fünf etablierte Zelllinien verwendet, die embryonale Nierenzelllinie HEK-293 und vier ccRCC-Zelllinien (Caki-1, Caki-2, 769-P, 786-O), welche sich in ihrer Expression der Proteine NNMT und VHL unterscheiden.
Zudem wurde eine stabile Zelllinie aus den Caki-2 Zellen generiert, die durch ein Doxycyclin induzierbares Tet-On-System NNMT vermehrt exprimiert (C2NNMTs).
Es wurden sowohl molekularbiologische als auch biochemische Methoden zur Analyse angewendet.
Die Zelllinien wurden für Transfektionsstudien zur Überexpression oder zum Knockdown von NNMT genutzt, um die Einflussnahme auf die Enzyme Nikotinamid-phosphoribosyltransferase (NAMPT), Sirtuin 1 (SIRT1), Methioninadenosyltransferase-2 β-Untereinheit (MAT2B) und Aldehydoxidase (AOX1) zu analysieren.
Da SAM (S-Adenosylmethionin) der Methyldonor von NNMT ist, wurde auch der Einfluss der Methioninkonzentration betrachtet. Viele der bisherigen publizierten Versuche wurden bei 100 µM Methionin durchgeführt, was jedoch nicht der humanen Serumkonzentration entspricht, welche bei 20 µM Methionin liegt.
Umfangreiche massenspektrometrische Analysen führten zur Identifizierung weiterer Proteine, welche durch die NNMT-Modulation beeinflusst wurden. Die Identifikation einer Vielzahl veränderter Targets verdeutlichte den Einfluss auf den Energiemetabolismus bis hin zur Apoptose. Es zeigten sich unterschiedliche Regulationen von Glykolyse-, Respirations-, Citratzyklus-, Pentosephosphatweg- und Lipidsyntheseproteinen. Insgesamt ergaben sich individuelle, zellspezifische Regulierungen, welche auf die Sirtuine zurückzuführen sind.
Weiterhin wurden Untersuchungen zur erhöhten Expression von NNMT unter Einfluss von Nikotinamid (NAM) sowie Interleukin-6 (IL-6) durchgeführt. Die Analysen zeigten, dass zwischen der Pseudohypoxie und der Erhöhung der NNMT-Expression ein Zusammenhang besteht, denn IL-6 phosphoryliert ERK (engl. Extracellular-signal Regulated Kinases) und STAT3 (engl. Signal transducer and activator of transcription 3), welche beide benötigt werden, um die Transkription des NNMT-Gens zu beeinflussen und die NNMT-Proteinexpression zu fördern.
Die Ergebnisse dieser Untersuchungen sollen dazu dienen, die biochemischen Zusammenhänge einer veränderten Expression von NNMT besser zu verstehen und damit neue diagnostische Ansätze zu ermöglichen.