Biocatalytic Routes to Enantiomerically Enriched Dibenz[<i>c</i>,<i>e</i>]azepines

France, Scott P.; Aleku, Godwin A.; Sharma, Mahima; Mangas‐Sánchez, Juan; Howard, Roger M.; Steflik, Jeremy; Kumar, Rajesh; Adams, Ralph W.; Slabu, Iustina; Crook, Robert; Grogan, Gideon; Wallace, Timothy W.; Turner, Nicholas J.

doi:10.1002/ange.201708453

Cited by 15 publications

(9 citation statements)

References 43 publications

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“…Interestingly, diffraction quality crystals could only be obtained with cofactor present in the crystallization cocktail. We observed positive difference electron density inside the active site of the enzyme at a position equivalent to that of substrate molecules in other IRED structures in the literature [16][17][18][19], which was of a similar shape in all the crystal structures we obtained, independent of whether we used NADPH or NADP + , which substrate or cryoprotectants we used or if we utilized soaking or co-crystallization methods (Figure S4).…”

Section: Substrate-binding Sitesupporting

confidence: 73%

“…Therefore, it might be necessary to stabilize the transitional state in which the substrate is bound to the enzyme in a protonated state and to inhibit the enzyme’s capability to complete the reduction mechanism in order to limit dissolution of the S -IRED- Ms -substrate complex and stabilize it for crystallization. This could potentially be achieved by utilizing positively charged iminium ions which have been demonstrated to be valid substrates before and redox-inactive cofactor analogues like NADPH 4 which has been used to crystallize the closely related At RedAm with a synthetic substrate [ 18 , 43 ]. Another, albeit more complex strategy to understand the role and mechanism of IREDs could involve identifying their respective endogenous substrates via untargeted and combination metabolomics approaches [ 46 , 47 ].…”

Section: Discussionmentioning

confidence: 99%

“…Crystallographic studies so far indicate a close similarity in the overall structure of these enzymes. They consist of an N-terminal Rossmann-fold and a C-terminal helical domain, connected by a long interdomain helix, and constitute a catalytically active dimer by reciprocal domain sharing [ 13 , 14 , 15 , 16 , 17 , 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

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Structural Characterization of an S-enantioselective Imine Reductase from Mycobacterium Smegmatis

et al. 2020

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NADPH-dependent imine reductases (IREDs) are enzymes capable of enantioselectively reducing imines to chiral secondary amines, which represent important building blocks in the chemical and pharmaceutical industry. Since their discovery in 2011, many previously unknown IREDs have been identified, biochemically and structurally characterized and categorized into families. However, the catalytic mechanism and guiding principles for substrate specificity and stereoselectivity remain disputed. Herein, we describe the crystal structure of S-IRED-Ms from Mycobacterium smegmatis together with its cofactor NADPH. S-IRED-Ms belongs to the S-enantioselective superfamily 3 (SFam3) and is the first IRED from SFam3 to be structurally described. The data presented provide further evidence for the overall high degree of structural conservation between different IREDs of various superfamilies. We discuss the role of Asp170 in catalysis and the importance of hydrophobic amino acids in the active site for stereospecificity. Moreover, a separate entrance to the active site, potentially functioning according to a gatekeeping mechanism regulating access and, therefore, substrate specificity is described.

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Section: Substrate-binding Sitesupporting

confidence: 73%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Structural Characterization of an S-enantioselective Imine Reductase from Mycobacterium Smegmatis

et al. 2020

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“…AtRedAm proved to be a superior target protein for crystallization overall, and we had recently determined its structure in complex with a dibenzazepine imine substrate and a redox-inactive cofactor analog, NADPH 4 . 28 Herein, we report the AtRedAm structure determined in complex with the cofactor NADPH alone and also ternary complexes featuring NADPH with either ethyl levulinate (2) or ethyl 5-oxohexanoate (3) (Scheme 2b; for data collection and refinement statistics see section S7, Table S11, SI). In common with IREDs 21,29−31 and also AspRedAm, 27 the AtRedAm monomer features an N-terminal Rossmann domain attached to a C-terminal helical bundle by an interdomain helix.…”

Section: ■ Crystal Structures Of Atredam In Complex With Cofactors An...mentioning

confidence: 99%

A Mechanism for Reductive Amination Catalyzed by Fungal Reductive Aminases

Sharma

Mangas‐Sánchez²,

Aleku³

et al. 2018

ACS Catal.

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127

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Reductive aminases (RedAms) catalyze the asymmetric reductive amination of ketones with primary amines to give secondary amine products. RedAms have great potential for the synthesis of bioactive chiral amines; however, insights into their mechanism are currently limited. Comparative studies on reductive amination of cyclohexanone with allylamine in the presence of RedAms, imine reductases (IREDs), or NaBH3CN support the distinctive activity of RedAms in catalyzing both imine formation and reduction in the reaction. Structures of AtRedAm from Aspergillus terreus, in complex with NADPH and ketone and amine substrates, along with kinetic analysis of active-site mutants, reveal modes of substrate binding, the basis for the specificity of RedAms for reduction of imines over ketones, and the importance of domain flexibility in bringing the reactive participants together for the reaction. This information is used to propose a mechanism for their action and also to expand the substrate specificity of RedAms using protein engineering.

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“…110 Stereocomplementary biocatalysts are key assets for the synthesis of drugs and complex molecules. 94,[111][112][113][114][115][116][117][118][119] Upon exploring a collection of heme enzymes, the 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 Arnold group was able to identify a set of biocatalysts useful for producing the four possible stereoisomers of a cyclopropanation reaction with ethyl diazoacetate and an unactivated alkene (Scheme 2B). 120 Notably, no iron-based catalyst was previously known for this transformation and heme alone only catalyzed this reaction with < 1 turnover.…”

Section: Laboratory-evolved P450s For Biocatalytic Oxidationsmentioning

confidence: 99%

A Continuing Career in Biocatalysis: Frances H. Arnold

2019

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On the occasion of Professor Frances H. Arnold's recent acceptance of the 2018 Nobel Prize in Chemistry, we honor her numerous contributions to the fields of directed evolution and biocatalysis. Arnold pioneered the development of directed evolution methods for engineering enzymes as biocatalysts. Her highly interdisciplinary research has provided a ground not only for understanding the mechanisms of enzyme evolution but also for developing commercially viable enzyme biocatalysts and biocatalytic processes. In this Account, we highlight some of her notable contributions in the past three decades in the development of foundational directed evolution methods and their applications in the design and engineering of enzymes with desired functions for biocatalysis. Her work has created a paradigm shift in the broad catalysis field.

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Biocatalytic Routes to Enantiomerically Enriched Dibenz[c,e]azepines

Cited by 15 publications

References 43 publications

Structural Characterization of an S-enantioselective Imine Reductase from Mycobacterium Smegmatis

Structural Characterization of an S-enantioselective Imine Reductase from Mycobacterium Smegmatis

A Mechanism for Reductive Amination Catalyzed by Fungal Reductive Aminases

A Continuing Career in Biocatalysis: Frances H. Arnold

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