Mechanistic Insight toward Understanding the Role of Charge in Thiourea Organocatalysis

Smajlagic I.; Guest M.; Durán R.; Herrera B.; Dudding T.

Abstract

Pyranylation and glycosylation are pivotal for accessing a myriad of natural products, pharmaceuticals, and drug candidates. Catalytic approaches for enabling these transformations are of utmost importance and integral to advancing this area of synthesis. In exploring this chemical space, a combined experimental and computational mechanistic study of pyranylation and 2-deoxygalactosylation catalyzed by a cationic thiourea organocatalyst is reported. To this end, a thiourea-cyclopropenium organocatalyst was employed as a model system in combination with an arsenal of mechanistic techniques, including C-13 kinetic isotope effect experiments, deuterated labeling studies, variable-temperature H-1 NMR spectroscopy, and density functional theory calculations. From these studies, two distinct reaction pathways were identified for this transformation corresponding to either dual hydrogen bond (H-bond) activation or Bronsted acid catalysis. The former involving thiourea orchestrated bifurcated hydrogen bonding proceeded in an asynchronous concerted fashion. In contrast, the latter stepwise mechanism involving Bronsted acid catalysis hinged upon the formation of an oxocarbenium intermediate accompanied by subsequent alcohol addition.

Más información

Título según WOS: Mechanistic Insight toward Understanding the Role of Charge in Thiourea Organocatalysis
Título según SCOPUS: Mechanistic Insight toward Understanding the Role of Charge in Thiourea Organocatalysis
Título de la Revista: Journal of Organic Chemistry
Volumen: 85
Número: 2
Editorial: American Chemical Society
Fecha de publicación: 2020
Página de inicio: 585
Página final: 593
Idioma: English
DOI:

10.1021/acs.joc.9b02682

Notas: ISI, SCOPUS