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Chloroformate-mediated ring cleavage of indole alkaloids leads to re-engineered antiplasmodial agents.

Daniel C SchultzAlejandra Chávez-RiverosMichael G GoertzenBeau R BrummelRaphaella A PaesNatalia M SantosSrinivasarao TennetiKhalil A AbboudJames R RoccaGustavo SeabraChenglong LiDebopam ChakrabartiRobert William Huigens
Published in: Organic & biomolecular chemistry (2024)
Natural product ring distortion strategies have enabled rapid access to unique libraries of stereochemically complex compounds to explore new chemical space and increase our understanding of biological processes related to human disease. Herein is described the development of a ring-cleavage strategy using the indole alkaloids yohimbine, apovincamine, vinburnine, and reserpine that were reacted with a diversity of chloroformates paired with various alcohol/thiol nucleophiles to enable the rapid synthesis of 47 novel small molecules. Ring cleavage reactions of yohimbine and reserpine produced two diastereomeric products in moderate to excellent yields, whereas apovincamine and vinburnine produced a single diastereomeric product in significantly lower yields. Free energy calculations indicated that diastereoselectivity regarding select ring cleavage reactions from yohimbine and apovincamine is dictated by the geometry and three-dimensional structure of reactive cationic intermediates. These compounds were screened for antiplasmodial activity due to the need for novel antimalarial agents. Reserpine derivative 41 was found to exhibit interesting antiplasmodial activities against Plasmodium falciparum parasites (EC 50 = 0.50 μM against Dd2 cultures), while its diastereomer 40 was found to be three-fold less active (EC 50 = 1.78 μM). Overall, these studies demonstrate that the ring distortion of available indole alkaloids can lead to unique compound collections with re-engineered biological activities for exploring and potentially treating human disease.
Keyphrases
  • plasmodium falciparum
  • dna binding
  • induced pluripotent stem cells
  • molecular dynamics
  • density functional theory
  • water soluble