ABSTRACT
We report the first chemical synthesis of eurysterolâ A, a cytotoxic and antifungal marine steroidal sulfate with a unique C8-C19 oxy-bridged cholestane skeleton. After C19 hydroxylation of cholesteryl acetate, used as an inexpensive commercial starting material, the challenging oxidative functionalization of ringâ B was achieved by two different routes to set up a 5α-hydroxy-7-en-6-one moiety. As a key step, an intramolecular oxa-Michael addition was exploited to close the oxy-bridge (8ß,19-epoxy unit). DFT calculations show this reversible transformation being exergonic by about -30â kJ mol-1 . Along the optimized (scalable) synthetic sequence, the target natural product was obtained in only 11â steps in 5 % overall yield. In addition, an access to (isomeric) 7ß,19-epoxy steroids with a previously unknown pentacyclic ring system was discovered.
Subject(s)
Antifungal Agents/chemical synthesis , Steroids/chemistry , Sterols/chemical synthesis , Antifungal Agents/chemistry , Hydroxylation , Isomerism , Molecular Structure , Oxidation-Reduction , Sterols/chemistryABSTRACT
Cu/TEMPO catalyst systems are known for the selective transformation of alcohols to aldehydes, as well as for the simultaneous coupling of alcohols and amines to imines under oxidative conditions. In this study, such a Cu/TEMPO catalyst system is found to catalyze the N-formylation of a variety of amines by initial oxidative activation of methanol as the carbonyl source via formaldehyde and formation of N,O-hemiacetals and oxidation of the latter under very mild conditions. A vast range of amines, including aromatic and aliphatic, primary and secondary, and linear and cyclic amines are formylated under these conditions with good to excellent yields. Moreover, paraformaldehyde can be used instead of methanol for the N-formylation.