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Total synthesis reveals atypical atropisomerism in a small-molecule natural product, tryptorubin A

Solomon H. Reisberg, Yang Gao, Allison S. Walker, Eric J. N. Helfrich, Jon Clardy, Phil S. Baran

2020Science133 citationsDOIOpen Access PDF

Abstract

Molecular shape defines function in both biological and material settings, and chemists have developed an ever-increasing vernacular to describe these shapes. Noncanonical atropisomers-shape-defined molecules that are formally topologically trivial but are interconvertible only by complex, nonphysical multibond torsions-form a unique subset of atropisomers that differ from both canonical atropisomers (e.g., binaphthyls) and topoisomers (i.e., molecules that have identical connectivity but nonidentical molecular graphs). Small molecules, in contrast to biomacromolecules, are not expected to exhibit such ambiguous shapes. Using total synthesis, we found that the peptidic alkaloid tryptorubin A can be one of two noncanonical atropisomers. We then devised a synthetic strategy that drives the atropospecific synthesis of a noncanonical atrop-defined small molecule.

Topics & Concepts

AtropisomerNatural productMoleculeChemistryRing (chemistry)Small moleculeStereochemistryProduct (mathematics)Bicyclic moleculeOrganic chemistryMathematicsGeometryBiochemistryAxial and Atropisomeric Chirality SynthesisChemical synthesis and alkaloidsMolecular spectroscopy and chirality
Total synthesis reveals atypical atropisomerism in a small-molecule natural product, tryptorubin A | Litcius