Litcius/Paper detail

The Molecular Basis of Catalysis by SDR Family Members Ketoacyl‐ACP Reductase FabG and Enoyl‐ACP Reductase FabI in Type‐II Fatty Acid Biosynthesis

Jiashen Zhou, Lin Zhang, Lin Zhang, Yiran Wang, Wenyan Song, Yuzhou Huang, Yajuan Mu, Werner Schmitz, Shu‐Yu Zhang, Hou‐Wen Lin, Hongzhuan Chen, Fei Ye, Liang Zhang, Liang Zhang

2023Angewandte Chemie International Edition22 citationsDOIOpen Access PDF

Abstract

The short-chain dehydrogenase/reductase (SDR) superfamily members acyl-ACP reductases FabG and FabI are indispensable core enzymatic modules and catalytic orientation controllers in type-II fatty acid biosynthesis. Herein, we report their distinct substrate allosteric recognition and enantioselective reduction mechanisms. FabG achieves allosteric regulation of ACP and NADPH through ACP binding across two adjacent FabG monomers, while FabI follows an irreversible compulsory order of substrate binding in that NADH binding must precede that of ACP on a discrete FabI monomer. Moreover, FabG and FabI utilize a backdoor residue Phe187 or a "rheostat" α8 helix for acyl chain length selection, and their corresponding triad residues Ser142 or Tyr145 recognize the keto- or enoyl-acyl substrates, respectively, facilitating initiation of nucleophilic attack by NAD(P)H. The other two triad residues (Tyr and Lys) mediate subsequent proton transfer and (R)-3-hydroxyacyl- or saturated acyl-ACP production.

Topics & Concepts

StereochemistryCatalytic triadReductaseAllosteric regulationBiochemistryBiologyOxidoreductaseBiosynthesisEnzymeChemistryActive siteEnzyme Catalysis and ImmobilizationEnzyme Structure and FunctionMass Spectrometry Techniques and Applications
The Molecular Basis of Catalysis by SDR Family Members Ketoacyl‐ACP Reductase FabG and Enoyl‐ACP Reductase FabI in Type‐II Fatty Acid Biosynthesis | Litcius