Towards a Mechanistic Understanding of Factors Controlling the Stereoselectivity of Transketolase

Abstract

AbstractA structural model for thiamine‐diphosphate (ThDP)‐dependent transketolase (TK) was developed to analyse the effect of amino acid exchanges on the stereoselectivity of this synthetically important class of enzymes. In this study the carboligation of 3‐hydroxypyruvate as a donor and propanal, as well as pentanal, was studied. Based on literature data and additional mutagenesis studies using E. coli TK, a four‐state model was developed to explain the stereoselectivity of TKs by the relative orientation of donor and acceptor substrates in the active site prior to C−C‐bond formation. To enable a functional comparison of relevant amino acids of TKs from different species, a standard numbering scheme was developed. Using this concept, H26, H261, and F434 were identified as the key residues which mediate stereoselectivity, where two main factors influenced the arrangement of ThDP‐bound donor and acceptor prior to carboligation: the relative orientation of the substrate side chains and the orientation of the acceptor carbonyl group towards the donor hydroxy group. This model provides a first framework to understand the structure‐function relationships of TKs with respect to their stereoselectivity.