Highly Enantioselective, Hydrogen-Bond-Donor Catalyzed Additions to Oxetanes
datasetposted on 07.05.2020, 09:24 by Daniel A. Strassfeld, Zachary K. Wickens, Elias Picazo, Eric N. Jacobsen
A precisely designed chiral squaramide derivative is shown to promote the highly enantioselective addition of trimethylsilyl bromide (TMSBr) to a broad variety of 3-substituted and 3,3-disubstituted oxetanes. The reaction provides direct and general access to synthetically valuable 1,3-bromohydrin building blocks from easily accessed achiral precursors. The products are readily elaborated both by nucleophilic substitution and through transition-metal-catalyzed cross-coupling reactions. The enantioselective catalytic oxetane ring opening was employed as part of a three-step, gram-scale synthesis of pretomanid, a recently approved medication for the treatment of multidrug-resistant tuberculosis. Heavy-atom kinetic isotope effect (KIE) studies are consistent with enantiodetermining delivery of bromide from the H-bond-donor (HBD) catalyst to the activated oxetane. While the nucleophilicity of the bromide ion is expected to be attenuated by association to the HBD, overall rate acceleration is achieved by enhancement of Lewis acidity of the TMSBr reagent through anion abstraction.
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HBDgram-scale synthesismultidrug-resistant tuberculosisoxetane ring openingtrimethylsilyl bromideanion abstractionHydrogen-Bond-Donor Catalyzed Additionstransition-metal-catalyzed cross-coupling reactionsachiral precursorschiral squaramidebromide ionisotope effectenantioselective additionnucleophilic substitutionLewis acidityrate accelerationKIETMSBr reagentenantiodetermining delivery