Computational Study Focusing on a Comprehensive Conformational Analysis of Transition States for Aza-Spiro Ring Formations with N -Alkoxyamides.

An accurate understanding of conformations in transition states is a critical piece in the theoretical analysis of complex molecular reactions. In this study, we investigated conformationally diverse transition states during intramolecular aza-spiro ring formation with an allylsilane moiety and N -alkoxy iminium ion, a key reaction in the synthesis of fasicularin by Sato and Chida et al. , and identified the origins of stereoselectivity of the cyclization. A large number of conformational isomers with forming C-C bonds were comprehensively analyzed using Cremer-Pople puckering parameters. It was found that the conformations of the transition states had different puckering preferences depending on the reactant's double-bond geometry and the product's stereochemical configuration. Furthermore, an asymmetric aza-spiro cyclization with a tolyl group as a chiral auxiliary was investigated, showing that conformational anchoring by both a CH-O hydrogen bond and the CH-π interaction was critical for the asymmetric induction.