Nicholas J. Weise scite author profile

Ammonia-lyases and aminomutases are mechanistically and structurally diverse enzymes which catalyze the deamination and/or isomerization of amino acids in nature by cleaving or shifting a C-N bond. Of the many protein families in which these enzyme activities are found, only a subset have been employed in the synthesis of optically pure fine chemicals or in medical applications. This review covers the natural diversity of these enzymes, highlighting particular enzyme classes that are used within industrial and medical biotechnology. These highlights detail the discovery and mechanistic investigations of these commercially relevant enzymes, along with comparisons of their various applications as stand-alone catalysts, components of artificial biosynthetic pathways and biocatalytic or chemoenzymatic cascades, and therapeutic tools for the potential treatment of various pathologies.

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Identification of Novel Bacterial Members of the Imine Reductase Enzyme Family that Perform Reductive Amination

France

et al. 2018

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Reductive amination of carbonyl compounds constitutes one of the most efficient ways to rapidly construct chiral and achiral amine frameworks. Imine reductase (IRED) biocatalysts represent a versatile family of enzymes for amine synthesis through NADPH‐mediated imine reduction. The reductive aminases (RedAms) are a subfamily of IREDs that were recently shown to catalyze imine formation as well as imine reduction. Herein, a diverse library of novel enzymes were expressed and screened as cell‐free lysates for their ability to facilitate reductive amination to expand the known suite of biocatalysts for this transformation and to identify more enzymes with potential industrial applications. A range of ketones and amines were examined, and enzymes were identified that were capable of accepting benzylamine, pyrrolidine, ammonia, and aniline. Amine equivalents as low as 2.5 were employed to afford up to >99 % conversion, and for chiral products, up to >98 % ee could be achieved. Preparative‐scale reactions were conducted with low amine equivalents (1.5 or 2.0) of methylamine, allylamine, and pyrrolidine, achieving up to >99 % conversion and 76 % yield.

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Synthesis of D‐ and L‐Phenylalanine Derivatives by Phenylalanine Ammonia Lyases: A Multienzymatic Cascade Process

et al. 2015

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The synthesis of substituted d-phenylalanines in high yield and excellent optical purity, starting from inexpensive cinnamic acids, has been achieved with a novel one-pot approach by coupling phenylalanine ammonia lyase (PAL) amination with a chemoenzymatic deracemization (based on stereoselective oxidation and nonselective reduction). A simple high-throughput solid-phase screening method has also been developed to identify PALs with higher rates of formation of non-natural d-phenylalanines. The best variants were exploited in the chemoenzymatic cascade, thus increasing the yield and ee value of the d-configured product. Furthermore, the system was extended to the preparation of those l-phenylalanines which are obtained with a low ee value using PAL amination.

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Biocatalytic transamination with near-stoichiometric inexpensive amine donors mediated by bifunctional mono- and di-amine transaminases

et al. 2017

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Single‐Biocatalyst Synthesis of Enantiopure d‐Arylalanines Exploiting an Engineered d‐Amino Acid Dehydrogenase

et al. 2016

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Ap ractical ande fficient biocatalytic synthesis of aromatic d-amino acids has been developed, based on the reductive amination of the corresponding a-keto acids via ar ecombinant whole cell system composed of an engineered dehydrogenase and cofactor recycling apparatus.T he reaction was shown to give excellent enantioselectivity (! 98%) and good yields at the preparative scale across ab road range of substrates.A dditionally,t he structureo ft he variant enzyme was solved to allow rationalisation of the observedr eactionr ates.T he engineered wholec ell catalyst was also used to mediate the production of d-phenylalanined erivatives from racemic mixtures and cheaper l-aminoa cids by combiningi tw ith an enantiocomplementary deaminase.

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Nicholas J. Weise

Synthetic and Therapeutic Applications of Ammonia-lyases and Aminomutases

Identification of Novel Bacterial Members of the Imine Reductase Enzyme Family that Perform Reductive Amination

Synthesis of D‐ and L‐Phenylalanine Derivatives by Phenylalanine Ammonia Lyases: A Multienzymatic Cascade Process

Biocatalytic transamination with near-stoichiometric inexpensive amine donors mediated by bifunctional mono- and di-amine transaminases

Single‐Biocatalyst Synthesis of Enantiopure d‐Arylalanines Exploiting an Engineered d‐Amino Acid Dehydrogenase

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