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Literature DB >> 27164259

A NADH-accepting imine reductase variant: Immobilization and cofactor regeneration by oxidative deamination.

Martin Gand¹, Christian Thöle¹, Hubertus Müller¹, Henrike Brundiek², Ghader Bashiri³, Matthias Höhne⁴.

Abstract

Engineering cofactor specificity of enzymes is a promising approach that can expand the application of enzymes for biocatalytic production of industrially relevant chemicals. Until now, only NADPH-dependent imine reductases (IREDs) are known. This limits their applications to reactions employing whole cells as a cost-efficient cofactor regeneration system. For applications of IREDs as cell-free catalysts, (i) we created an IRED variant showing an improved activity for NADH. With rational design we were able to identify four residues in the (R)-selective IRED from Streptomyces GF3587 (IR-Sgf3587), which coordinate the 2'-phosphate moiety of the NADPH cofactor. From a set of 15 variants, the highest NADH activity was caused by the single amino acid exchange K40A resulting in a 3-fold increased acceptance of NADH. (ii) We showed its applicability using an immobilisate obtained either from purified enzyme or from lysate using the EziG(™) carriers. Applying the variant and NADH, we reached 88% conversion in a preparative scale biotransformation when employing 4% (w/v) 2-methylpyrroline. (iii) We demonstrated a one-enzyme cofactor regeneration approach using the achiral amine N-methyl-3-aminopentanone as a hydrogen donor co-substrate.

Entities: Chemical Mutation Species

Keywords: Cofactor specificity; Coupled oxidative deamination; Imine reductase; Immobilization; Preparative scale biocatalysis; Rational design

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Year: 2016 PMID： 27164259 DOI： 10.1016/j.jbiotec.2016.05.006

Source DB: PubMed Journal: J Biotechnol ISSN： 0168-1656 Impact factor: 3.307

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Cited

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7. Systematic Evaluation of Imine-Reducing Enzymes: Common Principles in Imine Reductases, β-Hydroxy Acid Dehydrogenases, and Short-Chain Dehydrogenases/ Reductases.

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