Engineering an Enantioselective Amine Oxidase for the Synthesis of Pharmaceutical Building Blocks and Alkaloid Natural Products

Ghislieri, Diego; Green, Anthony P.; Pontini, Marta; Willies, Simon C.; Rowles, Ian; Frank, Albin; Grogan, Gideon; Turner, Nicholas J.

doi:10.1021/ja4051235

Cited by 329 publications

(232 citation statements)

References 36 publications

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“…Recently, Ghislieri et al (2013) designed a toolbox for the development of MAO-N variants applicable in asymmetric synthesis of the generic active pharmaceutical ingredients Solifenacin and Levocetirizine, as well as the natural products (R)-coniine, (R)-eleagnine, (R)-leptaflorine and (R)-harmicine.…”

Section: Introductionmentioning

confidence: 99%

Immobilised whole-cell recombinant monoamine oxidase biocatalysis

Zajkoska

Rosenberg

Heath

et al. 2014

Appl Microbiol Biotechnol

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This work demonstrates the first example of the immobilisation of MAO-N whole cells to produce a biocatalyst that remained suitable for repetitive use after 11 months of storage and stable up to 15 months after immobilisation. The production of Escherichia coli expressing recombinant MAO-N was scaled up to bioreactors under regulated, previously optimised conditions (10% DO, pH 7), and the amount of biomass was almost doubled compared to flask cultivation. Subsequently, pilot immobilisation of the whole-cell biocatalyst using LentiKats technology was performed. The amount of the immobilised biomass was optimised and the process was scaled up to a production level by immobilising 15 g of dry cell weight per litre of polyvinyl alcohol to produce 3 kg of whole-cell ready-to-use biocatalyst. The immobilised biocatalyst retained its initial activity over six consecutive biotransformations of the secondary amine model compound 3-azabicylo [3,3,0]octane, a building block of the hepatitis C drug telaprevir. Consecutive cultivation cycles in growth conditions not only increased the initial specific activity of biocatalyst produced on the industrial plant by more than 30%, but also significantly increased the rate of the biotransformation compared to the non-propagated biocatalyst.

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Section: Introductionmentioning

confidence: 99%

Immobilised whole-cell recombinant monoamine oxidase biocatalysis

Zajkoska

Rosenberg

Heath

et al. 2014

Appl Microbiol Biotechnol

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“…Accordingly, a one-pot/two-step methodology allowed the direct conversion of diallyl malonates into cyclic monoacid esters in aqueous media (Scheme 13C). Recently, and following this idea (Ru-catalyzed RCM + enzymatic organic transformations), Turner, Castagnolo and co-workers have reported the combination of the Ru-catalyzed ring-closing metathesis of diallyl anilines (to produce the corresponding 3-pyrrolines) and the subsequent biocatalytic aromatization of the resulting heterocycles (mediated by whole cells containing monoamine oxidases MAO-N variants D5, D9 and D11 [82][83][84] or the nicotine oxidase biocatalyst 6-HDNO (HDNO = 6-hydroxy-D-nicotine oxidase) [85]) for the synthesis of pyrroles in aqueous media (Scheme 14) [77]. In this case, and in contrast to the aforementioned results reported by Gröger, the authors firstly parametrized the biocatalytic transformation, thus studying the aromatization of different 3-pyrrolines promoted by monoamine oxidases MAO-N or 6-HDNO (Scheme 14A).…”

Section: Combination Of Ru-catalyzed Ring-closing Metathesis Of Diallmentioning

confidence: 99%

One-Pot Combination of Metal- and Bio-Catalysis in Water for the Synthesis of Chiral Molecules

2018

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During the last decade, the combination of different metal-and bio-catalyzed organic reactions in aqueous media has permitted the flourishing of a variety of one-pot asymmetric multi-catalytic reactions devoted to the construction of enantiopure and high added-value chemicals under mild reaction conditions (usually room temperature) and in the presence of air. Herein, a comprehensive account of the state-of-the-art in the development of catalytic networks by combining metallic and biological catalysts in aqueous media (the natural environment of enzymes) is presented. Among others, the combination of metal-catalyzed isomerizations, cycloadditions, hydrations, olefin metathesis, oxidations, C-C cross-coupling and hydrogenation reactions, with several biocatalyzed transformations of organic groups (enzymatic reduction, epoxidation, halogenation or ester hydrolysis), are discussed.

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“…[114] Furthermore, the development of a new D11 variant, which possessed high activity and excellent stereoselectivity toward bulky substrates, was accomplished. This enzyme was applied to the deracemization of Solefenacin, a competitive muscarinic acetylcholine receptor antagonist, and several Levocetirizine precursors, an antihistamine drug, thus expanding the substrate scope of MAO-N. For instance, the deracemization of 4-chlorobenzhydrylamine for the production of the (R)-configured amine was carried out with excellent enantiomeric excess (97%) and moderate isolated yield (45%, Scheme 18a).…”

Section: Scheme 17mentioning

confidence: 99%

“…[115] Scheme 18. a) Deracemization of a Levocitirizine motif using a MAO variant and the ammonia-borane complex. [114] b) Deracemization of β-carbolines using MAO-N-D10 and MAO-N-D11. [115] Using new strategies…”

Section: Scheme 17mentioning

confidence: 99%

Why Leave a Job Half Done? Recent Progress in Enzymatic Deracemizations

Díaz‐Rodríguez¹,

Lavandera

Gotor³

2015

CGC

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Abstract. In recent years the usefulness of enzymatic systems to obtain a single stereoisomerically pure compound starting from a racemate has been expanded. Moreover, current advances in protein engineering, molecular biology and modeling tools are the basis to improve the catalytic properties of enzymes to face novel synthetic challenges. Also, medium engineering and novel immobilization methods of (bio)catalysts are enhancing the productivity of biocatalytic processes making them suitable for being scalable. The development of multienzymatic protocols and the combination of enzymes with other catalysts are providing a wide range of synthetic possibilities that are expanding the scope of these transformations even at industrial scale. Herein we will describe an overview of recent (chemo)enzymatic deracemizations, focusing on the strategy employed (dynamic kinetic resolution, stereoinversion, cyclic deracemization or enantioconvergent process), the type of substrate (e.g., alcohols, amines, carboxylic acid derivatives or carbonylic compounds), and the biocatalyst(s) used.

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Engineering an Enantioselective Amine Oxidase for the Synthesis of Pharmaceutical Building Blocks and Alkaloid Natural Products

Cited by 329 publications

References 36 publications

Immobilised whole-cell recombinant monoamine oxidase biocatalysis

Immobilised whole-cell recombinant monoamine oxidase biocatalysis

One-Pot Combination of Metal- and Bio-Catalysis in Water for the Synthesis of Chiral Molecules

Why Leave a Job Half Done? Recent Progress in Enzymatic Deracemizations

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