TY - JOUR T1 - Molecular basis for two stereoselective Diels-Alderases that produce decalin skeletons JF - bioRxiv DO - 10.1101/2021.02.01.429105 SP - 2021.02.01.429105 AU - Keisuke Fujiyama AU - Naoki Kato AU - Suyong Re AU - Kiyomi Kinugasa AU - Kohei Watanabe AU - Ryo Takita AU - Toshihiko Nogawa AU - Tomoya Hino AU - Hiroyuki Osada AU - Yuji Sugita AU - Shunji Takahashi AU - Shingo Nagano Y1 - 2021/01/01 UR - http://biorxiv.org/content/early/2021/03/19/2021.02.01.429105.abstract N2 - Molecular chirality, discovered by Louis Pasteur in the middle of the 19th century1, is found in most primary and secondary metabolites. Particularly, the so-called natural products are rich in chiral centres2. The stereochemistry of natural products is strictly recognized in living organisms, and is thus closely related to their biological functions. The Diels–Alder (DA) reaction, which forms a six-membered ring with up to four chiral centres, is a fundamental practical reaction for C–C bond formation in synthetic chemistry3. Nature has also adopted this reaction to elaborate the complex structures of natural products using enzymes derived from various progenitor proteins4-7. Although enzymes catalysing the DA reaction, Diels–Alderases (DAases), have attracted increasing attention, little is known about the molecular mechanism by which they control the stereochemistry and perform catalysis. Here, we solved the X-ray crystal structures of a pair of decalin synthases, Fsa2 and Phm7, that catalyse intramolecular DA reactions to form enantiomeric decalin scaffolds during biosynthesis of the HIV-1 integrase inhibitor equisetin and its stereochemical opposite, phomasetin8,9. Based on the crystal structures, docking simulations followed by all-atom molecular dynamics simulations provided dynamic binding models demonstrating the folding of linear polyenoyl tetramic acid substrates in the binding pocket of these enzymes, explaining the stereoselectivity in the construction of decalin scaffolds. Site-directed mutagenesis studies verified the binding models and, in combination with density functional theory calculations, clarified how hydrophilic amino acid residues in the Phm7 pocket regulate and catalyse the stereoselective DA reaction. This study highlights the distinct molecular mechanisms of the enzymatic DA reaction and its stereoselectivity experimentally and computationally. We anticipate that clarified molecular mechanism herein provides not only the basic understanding how these important enzymes work but also the guiding principle to create artificial enzymes that produce designer bioactive molecules.Competing Interest StatementThe authors have declared no competing interest. ER -