Enzyme-Based Organic Synthesis. Cheanyeh Cheng

Enzyme-Based Organic Synthesis - Cheanyeh Cheng


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acceptor in general involves two steps: (i) the release of an amino group from the amino donor (deamination) and (ii) the addition of the amino group to the amino acceptor (amination). For this kind of transamination reaction, a vitamin B6‐based pyridoxal 5′‐phosphate (PLP) is required as a cofactor for transaminase to act as an intermediate amine acceptor and electron sink. Since the cofactor releases the amino group and restores its initial state at the end of the transamination, there is no need to carry out additional cofactor regeneration for the enzyme [1, 2]. However, the use of transaminases in organic synthesis still suffers from the problem of unfavorable reversible reaction equilibrium. This problem is especially serious when an amino acid is used as amino donor in the asymmetric synthesis of amines.

Chemical reaction depicting the transamination between acetophenone and excessive isopropyl amine with transaminase.

      Source: Truppo et al. [3].

      Another smart synthesis strategy is the combination of transaminase with other biocatalysts to form enzymatic cascade reactions that have been used to efficiently produce unnatural amino acids, optically pure amines, imines, secondary amines, and amides, or for the amination on the –OH or –CH3 functional group, or for the amines with two stereocenters. The enzymatic cascade reactions in organic synthesis give the advantages of shortening reaction routes, avoiding unstable or toxic intermediate, increasing the atom efficiency, and reducing the amount of wastes [1]. Most importantly, the enzymatic cascade reactions involving transaminases show prominent potential for many industrial applications [2].

      The conversion of the amide product in this enzymatic cascade reaction was up to 97% with an acyl transferase (AcT) from Mycobacterium smegmatis and an amine transaminase from Silicibacter pomeroyi.

Chemical reaction depicting enzyme cascade reactions for the conversion of l-threonine to l-homoalanine using a one-pot reaction process.

      Source: Modified from Park et al. [5].

Chemical reaction depicting the formation of N-benzylacetamide from benzaldehyde through an efficient one-pot biocatalytic amine transaminase/acyl transferase cascade.

      Source: Based on Land et al. [6].

Chemical reaction depicting the enzymatic cascade route toward all four diastereomers of 4-amino-1-phenylpentane-2-ol from a compound with two stereocenters.

      Source: Modified from Kohls et al. [7].

      The diketone was then used to prepare the remaining two diastereomers, (2S,4S)‐ and (2S,4R)‐1,3‐ amino alcohol, by first converting the diketone to (S)‐1,3‐hydroxy ketone and subsequently using either an (R)‐ or an (S)‐selective TA to stereoselective amination of the (S)‐1,3‐hydroxy ketone to (2S,4R)‐1,3‐amino alcohol and (2S,4S)‐1,3‐amino alcohol, respectively.


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