In the past decade it has become clear that many microbes harbor enzymes that employ an unusual flavin cofactor, the F420 deazaflavin cofactor. Herein we show that F420-dependent reductases (FDRs) can successfully perform enantio-, regio- and chemoselective ene-reductions. For the first time, we have demonstrated that F420H2-driven reductases can be used as biocatalysts for the reduction of α,β-unsaturated ketones and aldehydes with good conversions (>99%) and excellent regioselectivities and enantiomeric excesses (>99% ee). Noteworthily, FDRs typically display an opposite enantioselectivity when compared to the well established FMN-dependent Old Yellow Enzymes (OYEs).
F 420 -dependent enzymes are found in many microorganisms and can catalyze a wide range of redox reactions, including those with some substrates that are otherwise recalcitrant to enzyme-mediated reductions. Unfortunately, the scarceness of the cofactor prevents application of these enzymes in biocatalysis. The best F 420 -producing organism, Mycobacterium smegmatis, only produces 1.4 μmol per liter of culture. Therefore, we synthesized the unnatural cofactor FO-5′phosphate, coined FOP. The FO core-structure was chemically synthesized, and an engineered riboflavin kinase from Corynebacterium ammoniagenes (CaRFK) was then used to phosphorylate the 5′-hydroxyl group. The triple F21H/F85H/A66I CaRFK mutant reached 80% of FO conversion in 12 h. The same enzyme could produce 1 mg (2.5 μmol) of FOP in 50 mL of reaction volume, which translates to a production of 50 μmol/L. The activity toward FOP was tested for an enzyme of each of the three main structural classes of F 420 -dependent oxidoreductases. The sugar-6-phosphate dehydrogenase from Cryptosporangium arvum (FSD-Cryar), the F 420 :NADPH oxidoreductase from Thermobif ida fusca (TfuFNO), and the F 420 -dependent reductases from Mycobacterium hassiacum (FDR-Mha) all showed activity for FOP. Although the activity for FOP was lower than that for F 420 , with slightly lower k cat and higher K m values, the catalytic efficiencies were only 2.0, 12.6, and 22.4 times lower for TfuFNO, FSD-Cryar, and FDR-Mha, respectively. Thus, FOP could be a serious alternative for replacing F 420 and might boost the application of F 420 -dependent enzymes in biocatalysis.
Flavoprotein oxidases can catalyze oxidations of alcohols and amines by merely using molecular oxygen as the oxidant, making this class of enzymes appealing for biocatalysis. The FAD‐containing (FAD=flavin adenine dinucleotide) alcohol oxidase from P. chrysosporium facilitated double and triple oxidations for a range of aliphatic diols. Interestingly, depending on the diol substrate, these reactions result in formation of either lactones or hydroxy acids. For example, diethylene glycol could be selectively and fully converted into 2‐(2‐hydroxyethoxy)acetic acid. Such a facile cofactor‐independent biocatalytic route towards hydroxy acids opens up new avenues for the preparation of polyester building blocks.
Enzyme instability is an important limitation for the investigation and application of enzymes. Therefore, methods to rapidly and effectively improve enzyme stability are highly appealing. In this study we applied a computational method (FRESCO) to guide the engineering of an alcohol dehydrogenase. Of the 177 selected mutations, 25 mutations brought about a significant increase in apparent melting temperature (ΔTm ≥ +3 °C). By combining mutations, a 10-fold mutant was generated with a Tm of 94 °C (+51 °C relative to wild type), almost reaching water’s boiling point, and the highest increase with FRESCO to date. The 10-fold mutant’s structure was elucidated, which enabled the identification of an activity-impairing mutation. After reverting this mutation, the enzyme showed no loss in activity compared to wild type, while displaying a Tm of 88 °C (+45 °C relative to wild type). This work demonstrates the value of enzyme stabilization through computational library design.
Biocatalytic dealkylation of aryl methyl ethers is an attractive reaction for valorization of lignin components, as well as for deprotection of hydroxy functionalities in synthetic chemistry. We explored the demethylation of various aryl methyl ethers by using an oxidative demethylase from Pseudomonas sp. HR199. The Rieske monooxygenase VanA and its partner electron transfer protein VanB were recombinantly coexpressed in Escherichia coli and they constituted at least 25 % of the total protein content. Enzymatic transformations showed that VanB accepts NADH and NADPH as electron donors. The VanA–VanB system demethylates a number of aromatic substrates, the presence of a carboxylic acid moiety is essential, and the catalysis occurs selectively at the meta position to this carboxylic acid in the aromatic ring. The reaction is inhibited by the by‐product formaldehyde. Therefore, we tested three different cascade/tandem reactions for cofactor regeneration and formaldehyde elimination; in particular, conversion was improved by addition of formaldehyde dehydrogenase and formate dehydrogenase. Finally, the biocatalyst was applied for the preparation of protocatechuic acid from vanillic acid, giving a 77 % yield of the desired product. The described reaction may find application in the conversion of lignin components into diverse hydroxyaromatic building blocks and generally offers potential for new, mild methods for efficient unmasking of phenols.
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