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Tertiary alcohols have become interesting targets for organic synthesis themselves or as building blocks for valuable pharmaceutical compounds. However, the synthesis of optically pure tertiary alcohols is still a challenge both chemical and enzymatic means. Enzymes containing the GGG(A)X motif in the active site region have been known to show activity towards these sterically demanding substrates. Several tertiary alcohols have been resolved with high enantioselectivity by using this biocatalytic synthetic route. This thesis aims at providing a better understanding of enantiorecognition of GGG(A)X motif hydrolases in the enzymatic synthesis of enantiomerically enriched tertiary alcohols. Kinetic resolution of a wide range of tertiary alcohols using hydrolases provided insights on factors that can influence enantioselectivity of GGG(A)X motif enzymes. Additionally, a newly proposed chemoenzymatic method to synthesize protected alpha,alpha-dialkyl-alpha-hydroxycarboxylic acids has broadened the application of these enzymes to synthesize optically pure tertiary alcohols. Newly found biocatalysts through functional screening, database mining and rational protein design approaches provided a better enzyme platform for optically pure tertiary alcohol resolution.
Chiral amines represent high-value fine chemicals serving as key intermediate products in pharmaceutical, chemical and agrochemical industries. In the past decades, application of amine transaminases (ATAs) for stereoselective amination of prochiral ketones emerged to an environmentally benign and economically attractive alternative to transition metal-catalyzed asymmetric synthesis to afford optically pure amines at industrial scale. However, the restricted substrate scope of wild-type transaminases prohibited the conversion of particularly sterically demanding substrates, making protein engineering indispensable. The following thesis covers elaboration of a novel assay for transaminases (Article I) and identification and development of transaminase variants in order to achieve biocatalytic preparation of a set of pharmaceutically relevant model amines, ideally in optically pure form for both stereoisomers, preferentially using asymmetric synthesis and most preferably using isopropylamine as cost-efficient amine donor co-substrate (Article II-IV). The aforementioned target amines and the corresponding precursor ketones (see Scheme 4.1) were conceived and provided by the company F. Hoffmann-La Roche to attain suitable biocatalysts for a variety of potential intermediates for active pharmaceutical ingredients. Protein engineering of the transaminase scaffolds investigated in this thesis comprised: Initial screening for suitable starting enzyme scaffolds, structure-guided rational design of these scaffolds to enable bulky planar substrate acceptance, elaboration of a sequence motif, verification of the motif and preparative-scale asymmetric synthesis reactions (Article II). For non-planar and structurally different target substrates, namely spatially bulky or bi-cyclic bridged substrates, the transaminase variants were specifically refined and a different evolutionary route had to be pursued (Article III and Article IV). These results (Article II) represent not only the first successful endeavor to engineer a PLP-fold type I amine transaminase (commonly denoted as (S)-selective) for the conversion of highly sterically demanding substrates, but also generally expanded the scope of available fold type I amine transaminases by enzymes having a novel and exceptionally broad substrate spectrum. Aside from structure-guided rational protein engineering, as well non-rational methods, such as site-specific saturation mutagenesis or directed evolution, were applied for protein-engineering. In order to do so for all of the target compounds, a novel high-throughput solid phase activity assay for transaminases that was actually developed during the master thesis, was refined and published (Article I). In the context of this thesis, the same assay principle was as well adapted for quantification of specific activities in liquid phase (Article III). A comparison of different methodologies for developing agar plate assays and a detailed step by step protocol of our transaminase assay are illustrated in a book chapter.
In this work, the regioselectivity of different Baeyer-Villiger monooxygenases (BVMOs) for the conversion of selected substrates was reversed or improved by protein engineering. These studies highlight the importance of substrate positioning for the regioselectivity and that the position of the substrate can be efficiently influenced by introducing proper mutations. It was shown that the beneficial mutations for all BVMOs were partly in corresponding positions. Additionally, the sulfoxidation activity and the stability of BVMOs were targeted and improved by applying protein engineering.
Abstract
Methylation of free hydroxyl groups is an important modification for flavonoids. It not only greatly increases absorption and oral bioavailability of flavonoids, but also brings new biological activities. Flavonoid methylation is usually achieved by a specific group of plant O‐methyltransferases (OMTs) which typically exhibit high substrate specificity. Here we investigated the effect of several residues in the binding pocket of the Clarkia breweri isoeugenol OMT on the substrate scope and regioselectivity against flavonoids. The mutation T133M, identified as reported in our previous publication, increased the activity of the enzyme against several flavonoids, namely eriodictyol, naringenin, luteolin, quercetin and even the isoflavonoid genistein, while a reduced set of amino acids at positions 322 and 326 affected both, the activity and the regioselectivity of the methyltranferase. On the basis of this work, methylated flavonoids that are rare in nature were produced in high purity.
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.
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.
Abstract
A device for the transaminase‐catalysed synthesis combined with continuous recovery of chiral amines was designed. The system enabled the separation of the reaction components in three liquid phases: a reaction phase, an organic solvent phase (where the poorly water soluble ketone substrate was supplied), and an aqueous extraction phase for continuous product recovery. The transaminase‐mediated asymmetric synthesis of (S)‐1‐methyl‐3‐phenylpropylamine was employed as model reaction. Factors influencing the performance of the system, such as reactor geometry, working volumes and operating parameters, were investigated. Specifically, reaction yield and product recovery were enhanced by i) reducing the thickness of the reaction phase, while continuously stirring and ii) reducing the volume of the extraction phase. Under the optimal condition tested, 85 % of the product formed was extracted and a product concentration value of 9 g/L was reached. However, co‐extraction of the unreacted amine donor (17 %) was observed. Advantages and drawbacks of this process compared to existing technologies, as well as possible optimization strategies are discussed.
Abstract
Certain hydrolases preferentially catalyze acyl transfer over hydrolysis in an aqueous environment. However, the molecular and structural reasons for this phenomenon are still unclear. Herein, we provide evidence that acyltransferase activity in esterases highly correlates with the hydrophobicity of the substrate‐binding pocket. A hydrophobicity scoring system developed in this work allows accurate prediction of promiscuous acyltransferase activity solely from the amino acid sequence of the cap domain. This concept was experimentally verified by systematic investigation of several homologous esterases, leading to the discovery of five novel promiscuous acyltransferases. We also developed a simple yet versatile colorimetric assay for rapid characterization of novel acyltransferases. This study demonstrates that promiscuous acyltransferase activity is not as rare as previously thought and provides access to a vast number of novel acyltransferases with diverse substrate specificity and potential applications.
Abstract
Promiscuous acyltransferase activity is the ability of certain hydrolases to preferentially catalyze acyl transfer over hydrolysis, even in bulk water. However, poor enantioselectivity, low transfer efficiency, significant product hydrolysis, and limited substrate scope represent considerable drawbacks for their application. By activity‐based screening of several hydrolases, we identified the family VIII carboxylesterase, EstCE1, as an unprecedentedly efficient acyltransferase. EstCE1 catalyzes the irreversible amidation and carbamoylation of amines in water, which enabled the synthesis of the drug moclobemide from methyl 4‐chlorobenzoate and 4‐(2‐aminoethyl)morpholine (ca. 20 % conversion). We solved the crystal structure of EstCE1 and detailed structure–function analysis revealed a three‐amino acid motif important for promiscuous acyltransferase activity. Introducing this motif into an esterase without acetyltransferase activity transformed a “hydrolase” into an “acyltransferase”.