Steve M. Weinreb

Total Synthesis of Heterocyclic Natural Products

Professor Weinreb's research group is currently involved in the total synthesis of a number of complex heterocyclic natural products with significant pharmacological activity. Thoughout all of these projects, heavy emphasis is being placed on developing and exploiting new synthetic methodology of potentially wide application in organic chemistry. For example, the unusual polycyclic marine natural product sarain A will be synthesized from the tricyclic intermediate in Figure 1. This compound has been prepared via the key allylsilane-N-sulfonyliminium ion cyclization shown in the figure. In addition, work is presently in progress on total synthesis of the biogenetically related anticancer marine alkaloid madangamine A.

A novel method for amide oxidation has been developed using the free radical sequence shown in Figure 2. This process provides a simple, convenient access to N-acylimines, which are widely useful synthetic intermediates. This chemistry is now being applied in an approach to total synthesis of the marine sponge anticancer alkaloid fasicularin.

A new type of pericyclic ene reaction of allenylsilane imines and related compounds has recently been discovered (Figure 3). This methodology provides a stereospecific route to diverse functionalized nitrogen-containing ring systems. The chemistry is currently being utilized in enantioselective total syntheses of the poison frog neurotoxin (-)-gephyrotoxin and the indole alkaloid (-)-ibogamine.

Several other complex marine natural products are also presently targets for total synthesis. Included in this group is the unique hepatotoxin cylindro-spermopsin produced by a fresh water blue-green alga. The key steps in this synthesis utilize methodolgy previously developed in the Weinreb group. The approach involves the intramolecular N-sulfinylurea [4+2]-cycloaddition shown in Figure 4, followed by a stereospecific ring opening-allylic sulfoxide [2,3]-sigmatropic rearrangement.