ABSTRACT
The total syntheses of natural agelastatin A and agelastatin B were accomplished via a strategy that utilized an alkynyliodonium salt --> alkylidenecarbene --> cyclopentene transformation to convert a relatively simple amino alcohol derivative to the functionalized core of the agelastatin system. Subsequent manipulations delivered debromoagelastatin, which served as a precursor to both agelastatin A and agelastatin B. Alkylidenecarbene insertion chemoselectivity issues were explored en route to the final targets.
Subject(s)
Alkaloids/chemical synthesis , Alkynes/chemistry , Combinatorial Chemistry Techniques , Oxazolidinones/chemical synthesis , Animals , Cyclopentanes/chemical synthesis , Magnetic Resonance Spectroscopy , Molecular Structure , Porifera/chemistry , Salts/chemistryABSTRACT
The asymmetric total syntheses of (-)-agelastatin A and (-)-agelastatin B were accomplished in 14 steps each from (R)-epichlorohydrin. The pivotal transformation in both sequences was a sulfinate-promoted cyclization of an alkynyliodonium salt to furnish a key functionalized cyclopentene intermediate. Selective bromination in the final step led to either agelastatin A or agelastatin B, depending upon conditions.