Citrate as Cost-Efficient NADPH Regenerating Agent

The economically efficient utilization of NAD(P)H-dependent enzymes requires the regeneration of consumed reduction equivalents. Classically, this is done by substrate supplementation, and if necessary by addition of one or more enzymes. The simplest method thereof is whole cell NADPH regeneration. In this context we now present an easy-to-apply whole cell cofactor regeneration approach, which can especially be used in screening applications. Simply by applying citrate to a buffer or directly using citrate/-phosphate buffer NADPH can be regenerated by native enzymes of the TCA cycle, practically present in all aerobic living organisms. Apart from viable-culturable cells, this regeneration approach can also be applied with lyophilized cells and even crude cell extracts. This is exemplarily shown for the synthesis of 1-phenylethanol from acetophenone with several oxidoreductases. The mechanism of NADPH regeneration by TCA cycle enzymes was further investigated by a transient isotopic labeling experiment feeding [1,5-13C]citrate. This revealed that the regeneration mechanism can further be optimized by genetic modification of two competing internal citrate metabolism pathways, the glyoxylate shunt, and the glutamate dehydrogenase

Enzymatic and Chemoenzymatic Three-Step Cascades for the Synthesis of Stereochemically Complementary Trisubstituted Tetrahydroisoquinolines

Chemoenzymatic and enzymatic cascade reactions enable the synthesis of complex stereocomplementary 1,3,4-trisubstituted tetrahydroisoquinolines (THIQs) with three chiral centers in a step-efficient and selective manner without intermediate purification. The cascade employs inexpensive substrates (3-hydroxybenzaldehyde and pyruvate), and involves a carboligation step, a subsequent transamination, and finally a Pictet–Spengler reaction with a carbonyl cosubstrate. Appropriate selection of the carboligase and transaminase enzymes enabled the biocatalytic formation of (1R,2S)-metaraminol. Subsequent cyclization catalyzed either enzymatically by a norcoclaurine synthase or chemically by phosphate resulted in opposite stereoselectivities in the products at the C1 position, thus providing access to both orientations of the THIQ C1 substituent. This highlights the importance of selecting from both chemo- and biocatalysts for optimal results

Asymmetric synthesis of (S)-phenylacetylcarbinol – closing a gap in C–C bond formation

(S)-Phenylacetylcarbinol [(S)-PAC] and its derivatives are valuable intermediates for the synthesis of various active pharmaceutical ingredients (APIs), but their selective synthesis is challenging. As no highly selective enzymes or chemical catalysts were available, we used semi-rational enzyme engineering to tailor a potent biocatalyst to be >97% stereoselective for the synthesis of (S)-PAC. By optimizing the reaction and process used, industrially relevant product concentrations of >48 g L−1 (up to 320 mM) were achieved. In addition, the best enzyme variant gave access to a broad range of ring-substituted (S)-PAC derivatives with high stereoselectivity, especially for meta-substituted products

Motion for a Resolution tabled by Mr Barbi, Mr Vergeer, Mr Pedini, Mr Langes, Mr Penders, Mr Marck, Mrs Lenz, Mrs Walz, Mr Alber and Mrs Lentz-Cornette on behalf of the Group of the European People's Party (C-D Group) pursuant to Rule 47 of the Rules of Procedure on Nicaragua, Working Documents 1983-1984, Document 1-237/83, 26 April 1983

Peroxygenases offer an attractive means to address challenges in selective oxyfunctionalization chemistry. Despite this, their application in synthetic chemistry remains challenging due to their facile inactivation by the stoichiometric oxidant H2O2. Often atom-inefficient peroxide generation systems are required, which show little potential for large-scale implementation. Here, we show that visible-light-driven, catalytic water oxidation can be used for in situ generation of H2O2 from water, rendering the peroxygenase catalytically active. In this way, the stereoselective oxyfunctionalization of hydrocarbons can be achieved by simply using the catalytic system, water and visible light.Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.BT/BiocatalysisBN/Greg Bokinsky La

Conjugating his-tagged proteins to magnetic nanoparticles: tips and challenges

Resumen del póster presentado al 5th Multistep Enzyme Catalyzed Processes Congress (MECPC), celebrado online del 13 al 16 de septiembre de 2021.The histidine tag (His-tag) is one of the most used affinity-tag for protein purification due to its small size and versatility. Agarose and sepharose beads containing nitriloacetic acid (NTA) transition metal derivatives are widely used for the purification of His-tagged proteins, thanks to their high affinity to the His-tag genetically fused to the protein of interest [1]. The same chemistry can be used to conjugate enzymes to magnetic nanoparticles (MNPs) with the aim of tuning their activity by magnetic heating [2, 3]. Within the frame of the FET-OPEN project HOTZYMES (https://www.hotzymes.eu), different MNPs have been synthetized and coated with polyacrylic acid and dimercaptosuccinic acid, and then were further functionalized with NTA-Cu2+ as His-tag chelating agent. Different proteins were expressed as His-tag variants and immobilized on the MNPs, including monomeric (superfolded GFP), dimeric (C. violaceum transaminase, CvTA; C. uda cellobiose phosphorylase, CuCbP), and tetrameric (B. stearothermophilus alcohol dehydrogenase, ADH) variants. While for the monomeric protein selected as model no difficulties in the bioconjugation processes were observed, when using dimeric or tetrameric enzymes the aggregation of the MNPs occurs very easily due to crosslinking between the nanoparticles. This colloidal destabilization of the MNPs is favored due to its high surface area and the presence of several tags per enzyme molecule. To avoid this situation, different strategies have been developed: saturation of the binding site of the nanoparticles, presence of a small percentage of imidazole in reaction, changes in the incubation conditions (pH, ionic strength, …). First positive results confirm that by playing with different factors it is possible to conjugate different His-tagged enzymes to very different MNPs in terms of size, shape, surface area, and colloidal stability. Actually, it is possible to avoid protein and MNPs aggregation while obtaining good activity yields for the conjugated enzymes and maintaining the magnetic heating capacity of the MNPs.The research for this work has received funding from the European Union (EU) project HOTZYMES (grant agreement n° 829162) under EU’s Horizon 2020 Programme Research and Innovation actions H2020-FETOPEN-2018-2019-2020-01. Authors also thank Spanish MINECO project BIO2017-84246-C2-1-R, DGA and Fondos Feder (Bionanosurf E15_17R).Peer reviewe