β-Hydroxy-α-amino acids (βHAAs) are an essential class of building blocks of therapeutically important compounds and complex natural products. They contain two chiral centers at Cα and Cβ positions, resulting in four possible diastereoisomers. Many innovative asymmetric syntheses have been developed to access structurally diverse βHAAs. The main challenge, however, is the control of the relative and absolute stereochemistry of the asymmetric carbons in a sustainable way. In this respect, there has been considerable attention focused on the chemoenzymatic synthesis of βHAAs via a one-step process. Nature has evolved different enzymatic routes to produce these valuable βHAAs. Among these naturally occurring transformations, L-threonine transaldolases present potential biocatalysts to generate βHAAs in situ. 4-Fluorothreonine transaldolase from Streptomyces sp. MA37 (FTaseMA) catalyzes the cross-over transaldolation reaction between L-Thr and fluoroacetaldehyde to give 4-fluorothreonine and acetaldehyde (Ad). It has been demonstrated that FTaseMA displays considerable substrate plasticity toward structurally diverse aldehyde acceptors, leading to the production of various βHAAs. In this chapter, we describe methods for the preparation of FTaseMA, and the chemoenzymatic synthesis of βHAAs from various aldehydes and L-Thr using FTaseMA.
Keywords: 4-Fluorothreonine; 4-Fluorothreonine transaldolase; Beta-hydroxy-alpha-amino acids; Fluorometabolites; Streptomyces sp. MA37.
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