Expanding the Imine Reductase Toolbox by Exploring the Bacterial Protein‐Sequence Space

Wetzl, Dennis; Berrera, Marco; Sandon, Nicolas; Fishlock, Dan; Ebeling, Martin; Müller, Michael; Hanlon, Steven P.; Wirz, Beat; Iding, Hans

doi:10.1002/cbic.201500218

Cited by 105 publications

(120 citation statements)

References 29 publications

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The rapidly growing area of asymmetrici mine reduction by imine reductases (IREDs)h as provided alternative routes to chiral amines. [2][3][4] In addition, IREDs were recently utilized as chiral catalysts forr eductive aminations, and showedh igh chemoselectivity for reducing the imine intermediate formed in situ while leaving the C=Ob ond unaffected. Assisted by an in silico analysis of energy barriers, we evaluated asymmetric hydrogenationso f carbonyls and iminesw hile considering the influence of substrate reactivity on the chemoselectivity of this novel class of reductases.W er eport the asymmetric reduction of C=Na s well as C=Ob onds catalysed by members of the IRED enzyme family.

The biocatalytic, stereocontrolled addition of hydrogen from NAD(P)H to a,b-unsaturatedc arbonyl compounds, cyclic/acyclic imines and aldehydes/ketones during asymmetric catalytic transformationi sahighlye fficient and competitive alternative for the synthesis of chiral products.

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confidence: 99%

Asymmetric Ketone Reduction by Imine Reductases

et al. 2016

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The rapidly growing area of asymmetric imine reduction by imine reductases (IREDs) has provided alternative routes to chiral amines. Here we report the expansion of the reaction scope of IREDs by showing the stereoselective reduction of 2,2,2-trifluoroacetophenone. Assisted by an in silico analysis of energy barriers, we evaluated asymmetric hydrogenations of carbonyls and imines while considering the influence of substrate reactivity on the chemoselectivity of this novel class of reductases. We report the asymmetric reduction of C=N as well as C=O bonds catalysed by members of the IRED enzyme family.

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confidence: 99%

Asymmetric Ketone Reduction by Imine Reductases

et al. 2016

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“…With the starting materials and reference compounds in hand, analytical methods for determining the conversion (by achiral GC) and enantioselectivity (by chiral SFC‐HPLC) were established (see Experimental section). Attracted by the recent successful utilization of the IRED from Mycobacterium smegmatis for the reduction of a range of prochiral 3‐thiazolines , we next conducted synthetic experiments at substrate concentrations of 20 mM rac ‐ 1a and rac ‐ 1b in order to get an insight into the suitability of this IRED to form the desired products. Towards this end, we used a tailor‐made recombinant whole‐cell biocatalyst , which contains the IRED from M. smegmatis and the GDH from Bacillus subtilis for in situ recycling of the cofactor NADPH (utilized in catalytic amount) using D ‐glucose as a co‐substrate (Table ).…”

Section: Resultsmentioning

confidence: 99%

“…The IREDs from M. smegmatis is recombinantly expressed in Escherichia coli ( E. coli ) BL21(DE3), according to a literature‐known procedure . A preculture (10 mL LB medium, containing 100 μg/mL of carbenicillin) of E. coli BL21(DE3) carrying the recombinant plasmid is cultivated overnight at 37°C.…”

Section: Methodsmentioning

confidence: 99%

Biocatalytic Reduction of 2‐Monosubstituted 3‐Thiazolines Using Imine Reductases

Zumbrägel

Wagner

Weißing

et al. 2019

Journal of Heterocyclic Chem

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The application of a straightforward biocatalytic technology for the reduction of racemic 2‐monosubstituted 3‐thiazolines, which are easily prepared via Asinger‐multicomponent reaction, is reported. The biocatalytic reduction yields racemic 2‐monosubstituted 3‐thiazolidines, which are difficult to be prepared by means of classic chemical routes, in moderate to high yields. Moreover, our study clarifies the stereochemical reaction course of the biocatalytic reduction. Furthermore, the efficiency of this biocatalytic technology is demonstrated in an experiment at an elevated substrate concentration of 60 mM leading to 96% conversion.

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“…An SDR in the ADH family, tetrahydroalstonine synthase, from Catharanthus roseus has been shown to reduce the imine bond on strictosidine to form tetrahydroalstonine (Stavrinides et al, 2015). Several more NADPH dependent imine reductases have been characterized in bacteria (Wetzl et al, 2015). After this reduction, norbelladine has been shown to be methylated by the class I methyltransferase N4OMT in Narcissus sp.…”

Section: Amaryllidaceae Alkaloidsmentioning

confidence: 99%

The Amaryllidaceae alkaloids: biosynthesis and methods for enzyme discovery

Kilgore

Kutchan

2015

Phytochem Rev

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Amaryllidaceae alkaloids are an example of the vast diversity of secondary metabolites with great therapeutic promise. The identification of novel compounds in this group with over 300 known structures continues to be an area of active study. The recent identification of norbelladine 4′-O-methyltransferase (N4OMT), an Amaryllidaceae alkaloid biosynthetic enzyme, and the assembly of transcriptomes for Narcissus sp. aff. pseudonarcissus and Lycoris aurea highlight the potential for discovery of Amaryllidaceae alkaloid biosynthetic genes with new technologies. Recent technical advances of interest include those in enzymology, next generation sequencing, genetic modification, nuclear magnetic resonance spectroscopy (NMR), and mass spectrometry (MS).

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Expanding the Imine Reductase Toolbox by Exploring the Bacterial Protein‐Sequence Space

Cited by 105 publications

References 29 publications

Asymmetric Ketone Reduction by Imine Reductases

Asymmetric Ketone Reduction by Imine Reductases

Biocatalytic Reduction of 2‐Monosubstituted 3‐Thiazolines Using Imine Reductases

The Amaryllidaceae alkaloids: biosynthesis and methods for enzyme discovery

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