Rh(III)-Catalyzed C-2 Alkylation of Indoles followed by a Post-Synthetic Modification via the Ugi Reaction

Indole derivatives substituted at the C-2 position have shown important biological activities. Due to these properties, several methods have been described for the preparation of structurally diverse indoles. In this work, we have synthesized highly functionalized indole derivatives via Rh(III)-catalyzed C-2 alkylation with nitroolefins. Under the optimized condition, 23 examples were prepared with 39-80 % yield. Moreover, the nitro compounds were reduced and submitted to the Ugi four-component reaction, furnishing a series of new indole-peptidomimetics in moderate to good overall yields.

Rh-Catalyzed Direct Decarbonylative Borylation of Carboxylic Acids

Carboxylic acids are abundant, low cost and environmentally friendly, direct convert carboxylic acids into valued-added compounds are in high demand. Herein, we report a Rh(I) catalyzed direct decarbonylative borylation of aryl and alkyl carboxylic acid by using TFFH as activator. This protocol features excellent functional-group tolerance and a broad substrate scope including natural product and drugs. A gram-scale decarbonylative borylation reaction of Probenecid is also presented. In addition, the utility of this strategy is highlighted by a one-pot decarbonylative borylation/ derivatization sequence.

Catalytic NO Reduction by NO Pre-Adsorbed RhCeO2 NO- Clusters

A fundamental understanding on the dynamically structural evolution of catalysts induced by reactant gases under working conditions is challenging but pivotal in catalyst design. Herein, in combination with state-of-the-art mass spectrometry for cluster reactions, cryogenic photoelectron imaging spectroscopy, and quantum-chemical calculations, we identified that NO adsorption on rhodium-cerium bimetallic oxide cluster RhCeO₂ ^- can create a Ce³⁺ ion in product RhCeO₂ NO^- that serves as the starting point to trigger the catalysis of NO reduction by CO. Theoretical calculations substantiated that the reduction of another two NO molecules into N₂ O takes place exclusively on the Ce³⁺ ion while Rh behaves like a promoter to buffer electrons and cooperates with Ce³⁺ to drive NO reduction. Our finding demonstrates the importance of NO in regulating the catalytic behavior of Rh under reaction conditions and provides much-needed insights into the essence of NO reduction over Rh/CeO₂ , one of the most efficient components in three-way catalysts for NO_x removal.

Coupling of sterically hindered trisubstituted olefins and benzocyclobutenones by C-C activation: total synthesis and structural revision of cycloinumakiol

The first total syntheses of the proposed structure of cycloinumakiol (1) and its C5 epimer (18) are achieved in a concise and efficient fashion. Starting from the known 3-hydroxybenzocyclobutenone, 1 and 18 are obtained in nine and five steps with overall yields of 15% and 33%, respectively. The key for the success of this approach is the use of a catalytic C-C activation strategy for constructing the tetracyclic core of 1 through carboacylation of a sterically hindered trisubstituted olefin with benzocyclobutenone. In addition, the structure of the natural cycloinumakiol was reassigned to 19-hydroxytotarol (7) through X-ray diffraction analysis. This work demonstrates the potential of C-C activation for streamlining complex natural product synthesis.