An Efficient and Scalable “Second Generation” Total Synthesis of the Marine Polyketide Limaol Endowed with Antiparasitic Activity

Abstract

AbstractThe cluster of four skipped exo‐methylene substituents on the “northern” wing of limaol renders this dinoflagellate‐derived marine natural product unique in structural terms. This arguably non‐thermodynamic array gains kinetic stability by virtue of populating local conformations which impede isomerization to a partly or fully conjugated polyene. This analysis suggested that the difficulties encountered during the late stages of our first total synthesis of this polyketide had not been caused by an overly fragile character of this unusual substructure; rather, an unfavorable steric microenvironment about the spirotricyclic core was identified as the likely cause. To remedy the issue, the protecting groups on this central fragment were changed; in effect, this amendment allowed all strategic and practical problems to be addressed. As a result, the overall yield over the longest linear sequence was multiplied by a factor of almost five and the material throughput increased more than eighty‐fold per run. Key‐to‐success was a gold‐catalyzed spirocyclization reaction; the reasons why a Brønsted acid cocatalyst is needed and the origin of the excellent levels of selectivity were delineated. The change of the protecting groups also allowed for much improved fragment coupling processes; most notably, the sequence of a substrate‐controlled carbonyl addition reaction followed by Mitsunobu inversion that had originally been necessary to affix the southern tail to the core could be replaced by a reagent controlled asymmetric allylation. Finally, a much‐improved route to the “northern” sector was established by leveraging the power of asymmetric hydrogenation of a 2‐pyrone derivative. Limaol was found to combine appreciable antiparasitic activity with very modest cytotoxicity.