Your search keyword '"Knaus T"' showing total 9 results

1. CHAPTER 6. Bio-catalyzed Aerobic Oxidation Reactions

Author

Vilím, J., primary, Knaus, T., additional, and Mutti, F. G., additional

Published

2020

2. Biocatalyzed Aerobic Oxidation Reaction

Author

Vilím, J., Knaus, T., Mutti, F.G., Mejía, E., and Biocatalysis (HIMS, FNWI)

Subjects

chemistry.chemical_classification, Hydroxylation, chemistry.chemical_compound, chemistry, Oxidoreductase, Alcohol oxidation, Organic chemistry, Halogenation, Organic synthesis, Redox, Oxidative decarboxylation, Catalysis

Abstract

Oxidoreductase enzymes enable a large variety of oxidation and oxyfunctionalization reactions at the expense of molecular oxygen, which is most commonly used in the form of air and at atmospheric pressure. Over the past decade, the number of available enzymes and methodologies enabling the performance of these types of reactions has increased significantly, thereby greatly complicating the navigation of the biochemical landscape of aerobic enzymatic reactions. This chapter provides an overview of bio-catalytic reactions that utilize dioxygen as a final electron acceptor or hydroxylating agent with a focus on more mature processes that allow at least gram-scale biotransformations with significant chemical turnovers, thus demonstrating practical applicability in organic synthesis. The described aerobic bio-catalytic reactions comprise: (a) carbon–hydrogen hydroxylation or halogenation; (b) mono- or di-hydroxylation as well as epoxidation or cleavage of alkenes; (c) Baeyer–Villiger oxidation; (d) oxidation of alcohols or aldehydes; oxidative decarboxylation; (e) oxidation of amines or imines; oxidation of organosulfur, organoboron or organoselenium compounds; and (f) oxidative carbon–carbon bond formation. Additionally, this chapter provides brief and selected mechanistic insights into the enzyme classes (i.e., oxygenases, oxidases, and dehydrogenases) that catalyze these biochemical transformations with often excellent chemo-, regio- and stereoselectivities.

Published

2020

3. A high-performance electrochemical biosensor using an engineered urate oxidase.

Author

Wei Z, Knaus T, Liu Y, Zhai Z, Gargano AFG, Rothenberg G, Yan N, and Mutti FG

Subjects

Urate Oxidase, Gold, Carbon, Electrodes, Electrochemical Techniques, Enzymes, Immobilized, Metal Nanoparticles, Biosensing Techniques

Abstract

We constructed a high-performance biosensor for detecting uric acid by immobilizing an engineered urate oxidase on gold nanoparticles deposited on a carbon-glass electrode. This biosensor showed a low limit-of-detection (9.16 nM), a high sensitivity (14 μA/μM), a wide range of linearity (50 nM-1 mM), and more than 28 days lifetime.

Published

2023

4. Regio- and stereoselective multi-enzymatic aminohydroxylation of β-methylstyrene using dioxygen, ammonia and formate.

Author

Corrado ML, Knaus T, and Mutti FG

Abstract

We report an enzymatic route for the formal regio- and stereoselective aminohydroxylation of β-methylstyrene that consumes only dioxygen, ammonia and formate; carbonate is the by-product. The biocascade entails highly selective epoxidation, hydrolysis and hydrogen-borrowing alcohol amination. Thus, β-methylstyrene was converted into 1 R ,2 R and 1 S ,2 R -phenylpropanolamine in 59-63% isolated yields, and up to >99.5: <0.5 dr and er., Competing Interests: Conflicts of interest There are no conflicts to declare.

Published

2019

5. Efficient synthesis of enantiopure amines from alcohols using resting E. coli cells and ammonia.

Author

Houwman JA, Knaus T, Costa M, and Mutti FG

Abstract

α -Chiral amines are pivotal building blocks for chemical manufacturing. Stereoselective amination of alcohols is receiving increased interest due to its higher atom-efficiency and overall improved environmental footprint compared with other chemocatalytic and biocatalytic methods. We previously developed a hydrogen-borrowing amination by combining an alcohol dehydrogenase (ADH) with an amine dehydrogenase (AmDH) in vitro . Herein, we implemented the ADH-AmDH bioamination in resting Escherichia coli cells for the first time. Different genetic constructs were created and tested in order to obtain balanced expression levels of the dehydrogenase enzymes in E. coli . Using the optimized constructs, the influence of several parameters towards the productivity of the system were investigated such as the intracellular NAD + /NADH redox balance, the cell loading, the survival rate of recombinant E. coli cells, the possible toxicity of the components of the reaction at different concentrations and the influence of different substrates and cosolvents. In particular, the cofactor redox-balance for the bioamination was maintained by the addition of moderate and precise amounts of glucose. Higher concentrations of certain amine products resulted in toxicity and cell death, which could be alleviated by the addition of a co-solvent. Notably, amine formation was consistent using several independently grown E. coli batches. The optimized E. coli /ADH-AmDH strains produced enantiopure amines from the alcohols with up to 80% conversion and a molar productivity up to 15 mM. Practical applicability was demonstrated in a gram-scale biotransformation. In summary, the present E. coli -ADH-AmDH system represents an important advancement towards the development of 'green', efficient and selective biocatalytic processes for the amination of alcohols., Competing Interests: Conflicts of interest The authors declare to have no competing interests, or other interests that might be perceived to influence the results and/ or discussion reported in this article.

Published

2019

6. A biocatalytic method for the chemoselective aerobic oxidation of aldehydes to carboxylic acids.

Author

Knaus T, Tseliou V, Humphreys LD, Scrutton NS, and Mutti FG

Abstract

Herein, we present a study on the oxidation of aldehydes to carboxylic acids using three recombinant aldehyde dehydrogenases (ALDHs). The ALDHs were used in purified form with a nicotinamide oxidase (NOx), which recycles the catalytic NAD + at the expense of dioxygen (air at atmospheric pressure). The reaction was studied also with lyophilised whole cell as well as resting cell biocatalysts for more convenient practical application. The optimised biocatalytic oxidation runs in phosphate buffer at pH 8.5 and at 40 °C. From a set of sixty-one aliphatic, aryl-aliphatic, benzylic, hetero-aromatic and bicyclic aldehydes, fifty were converted with elevated yield (up to >99%). The exceptions were a few ortho-substituted benzaldehydes, bicyclic heteroaromatic aldehydes and 2-phenylpropanal. In all cases, the expected carboxylic acid was shown to be the only product (>99% chemoselectivity). Other oxidisable functionalities within the same molecule (e.g. hydroxyl, alkene, and heteroaromatic nitrogen or sulphur atoms) remained untouched. The reaction was scaled for the oxidation of 5-(hydroxymethyl)furfural (2 g), a bio-based starting material, to afford 5-(hydroxymethyl)furoic acid in 61% isolated yield. The new biocatalytic method avoids the use of toxic or unsafe oxidants, strong acids or bases, or undesired solvents. It shows applicability across a wide range of substrates, and retains perfect chemoselectivity. Alternative oxidisable groups were not converted, and other classical side-reactions (e.g. halogenation of unsaturated functionalities, Dakin-type oxidation) did not occur. In comparison to other established enzymatic methods such as the use of oxidases (where the concomitant oxidation of alcohols and aldehydes is common), ALDHs offer greatly improved selectivity., Competing Interests: Conflicts of interest The authors declare to have no competing interests, or other interests that might be perceived to influence the results and/ or discussion reported in this article.

Published

2018

7. In vitro biocatalytic pathway design: orthogonal network for the quantitative and stereospecific amination of alcohols.

Author

Knaus T, Cariati L, Masman MF, and Mutti FG

Abstract

The direct and efficient conversion of alcohols into amines is a pivotal transformation in chemistry. Here, we present an artificial, oxidation-reduction, biocatalytic network that employs five enzymes (alcohol dehydrogenase, NADP-oxidase, catalase, amine dehydrogenase and formate dehydrogenase) in two concurrent and orthogonal cycles. The NADP-dependent oxidative cycle converts a diverse range of aromatic and aliphatic alcohol substrates to the carbonyl compound intermediates, whereas the NAD-dependent reductive aminating cycle generates the related amine products with >99% enantiomeric excess (R) and up to >99% conversion. The elevated conversions stem from the favorable thermodynamic equilibrium (K' eq = 1.88 × 10 42 and 1.48 × 10 41 for the amination of primary and secondary alcohols, respectively). This biocatalytic network possesses elevated atom efficiency, since the reaction buffer (ammonium formate) is both the aminating agent and the source of reducing equivalents. Additionally, only dioxygen is needed, whereas water and carbonate are the by-products. For the oxidative step, we have employed three variants of the NADP-dependent alcohol dehydrogenase from Thermoanaerobacter ethanolicus and we have elucidated the origin of the stereoselective properties of these variants with the aid of in silico computational models.

Published

2017

8. Amine dehydrogenases: efficient biocatalysts for the reductive amination of carbonyl compounds.

Author

Knaus T, Böhmer W, and Mutti FG

Abstract

Amines constitute the major targets for the production of a plethora of chemical compounds that have applications in the pharmaceutical, agrochemical and bulk chemical industries. However, the asymmetric synthesis of α-chiral amines with elevated catalytic efficiency and atom economy is still a very challenging synthetic problem. Here, we investigated the biocatalytic reductive amination of carbonyl compounds employing a rising class of enzymes for amine synthesis: amine dehydrogenases (AmDHs). The three AmDHs from this study - operating in tandem with a formate dehydrogenase from Candida boidinii (Cb-FDH) for the recycling of the nicotinamide coenzyme - performed the efficient amination of a range of diverse aromatic and aliphatic ketones and aldehydes with up to quantitative conversion and elevated turnover numbers (TONs). Moreover, the reductive amination of prochiral ketones proceeded with perfect stereoselectivity, always affording the ( R )-configured amines with more than 99% enantiomeric excess. The most suitable amine dehydrogenase, the optimised catalyst loading and the required reaction time were determined for each substrate. The biocatalytic reductive amination with this dual-enzyme system (AmDH-Cb-FDH) possesses elevated atom efficiency as it utilizes the ammonium formate buffer as the source of both nitrogen and reducing equivalents. Inorganic carbonate is the sole by-product., Competing Interests: Competing financial interest The authors declare to have no competing interests, or other interests that might be perceived to influence the results and/or discussion reported in this article.

Published

2017

9. Systematic methodology for the development of biocatalytic hydrogen-borrowing cascades: application to the synthesis of chiral α-substituted carboxylic acids from α-substituted α,β-unsaturated aldehydes.

Author

Knaus T, Mutti FG, Humphreys LD, Turner NJ, and Scrutton NS

Subjects

Biotransformation, Carboxylic Acids metabolism, Chemistry Techniques, Synthetic, NAD metabolism, NADPH Dehydrogenase metabolism, Stereoisomerism, Aldehydes chemistry, Biocatalysis, Carboxylic Acids chemical synthesis, Carboxylic Acids chemistry, Hydrogen chemistry

Abstract

Ene-reductases (ERs) are flavin dependent enzymes that catalyze the asymmetric reduction of activated carbon-carbon double bonds. In particular, α,β-unsaturated carbonyl compounds (e.g. enals and enones) as well as nitroalkenes are rapidly reduced. Conversely, α,β-unsaturated esters are poorly accepted substrates whereas free carboxylic acids are not converted at all. The only exceptions are α,β-unsaturated diacids, diesters as well as esters bearing an electron-withdrawing group in α- or β-position. Here, we present an alternative approach that has a general applicability for directly obtaining diverse chiral α-substituted carboxylic acids. This approach combines two enzyme classes, namely ERs and aldehyde dehydrogenases (Ald-DHs), in a concurrent reductive-oxidative biocatalytic cascade. This strategy has several advantages as the starting material is an α-substituted α,β-unsaturated aldehyde, a class of compounds extremely reactive for the reduction of the alkene moiety. Furthermore no external hydride source from a sacrificial substrate (e.g. glucose, formate) is required since the hydride for the first reductive step is liberated in the second oxidative step. Such a process is defined as a hydrogen-borrowing cascade. This methodology has wide applicability as it was successfully applied to the synthesis of chiral substituted hydrocinnamic acids, aliphatic acids, heterocycles and even acetylated amino acids with elevated yield, chemo- and stereo-selectivity. A systematic methodology for optimizing the hydrogen-borrowing two-enzyme synthesis of α-chiral substituted carboxylic acids was developed. This systematic methodology has general applicability for the development of diverse hydrogen-borrowing processes that possess the highest atom efficiency and the lowest environmental impact.

Published

2015