Malonyl-thioesters are one of the major reactive intermediates in the biosynthesis of fatty acids and polyketides. Because fatty acids are essential to cellular life, the inhibition of fatty acid synthases is a viable mechanism for the generation of antimicrobials, anticancer agents and control of metabolic disease. Polyketides on the other hand are widely used as antibiotics and anticancer agents, making polyketide synthases targets for enzyme engineering. While most intermediates in fatty acid and polyketide biosynthesis are used in reversible reactions, malonyl-thioesters are created in and used in essentially irreversible reactions. This makes studying the enzyme:malonyl-thioester interactions virtually impossible because the malonyl-thioesters are destroyed in the process. To overcome this problem analogs of malonyl-thioesters were generated by other researchers. These analogs replace the thioester ketone with a thioether or oxetane, both of which are stable to enzymatic activity. However, neither of these analogs bind in enzyme active sites in catalytically relevant orientations. Thus, there is a critical need to develop stable malonyl-thioester isosteres capable of binding in enzyme active sites to elucidate molecular interactions and conformational changes leading to efficient catalysis. The objective of this proposal is to overcome problems associated with the natural malonyl-thioesters and previously synthesized isosteres. We have a panel of malonyl-thioesters that preserve a key ketone lost in the previous isosteres.
Our first aim i s to solve crystal or cryo-EM structures of acyl-CoA carboxylase enzymes in complex with our best isosteres to elucidate the enzyme:substrate interactions and conformational changes.
Our second aim i s to solve crystal, cryo-EM or NMR structures of ?-ketoacyl synthase enzymes in complex with our best isosteres to elucidate enzyme:substrate interactions and conformational changes. Together these studies will validate the use of malonyl-thioester analogs with carboxylate isosteres to capture enzyme:substrate interactions. Our structures will reveal conformational changes during catalysis that can be targeted for drug design and that need to be accounted for during enzyme engineering.
Major reactions in the synthesis of fatty acids and polyketides, molecules central to human health, remain cryptic due to the inherent reactivity of malonyl-thioesters. This proposal aims to generate malonyl-thoiester analogs to enable study of these reactions.