Abstract

The C2-C11 cyclized cembranoids, which include the eunicellins (also known as the cladiellins), briarellins, asbestinins, and sarcodictyins, are secondary metabolites isolated from gorgonian octocorals and soft corals. An unusual oxatricyclic ring system containing a hydroisobenzofuran and an oxonene unit with stereogenic centers residing at C1-3, 9, 10, and 14 is common to the eunicellins, briarellins, and asbestinins. However, the location of the cyclohexyl methyl groups (C11 versus C12) and the oxidation level of the sixand nine-membered rings differ among the three classes. Faulkner has proposed that the cyclization of the cembranoid diterpene skeleton initiates a biosynthetic pathway that leads to all four subclasses of these unusual molecules (Figure 1). Beginning with the cembrane skeleton, C2-C11 cyclization provides the cladiellin framework. An intramolecular etherification of the cladiellin tricycle affords the tetracyclic framework of the briarellin subclass, and a subsequent 1,2-suprafacial methyl shift of the briarellin structure is postulated to deliver the asbestinins as the class that is furthest evolved from the cembrane skeleton. The presence of multiple structural types in a common organism provides circumstantial evidence for Faulkner’s proposed biosynthetic pathway. The isolation of a cembrane metabolite with cladiellin metabolites in Alcyonium molle and with asbestinin metabolites in Briareum steckii are specific examples. The sarcodictyins are also proposed to arise from a C2-C11 cyclization of the cembrane skeleton; however, in these systems, the cyclization results in a fused cyclohexane and oxonane in place of the hydroisobenzofuran of the cladiellins, briarellins, and asbestinins. As a result of this significant structural variation of the sarcodictyins, the synthetic approaches to these molecules are quite different than those for the other three related subclasses. This review will cover efforts toward the eunicellins, briarellins, and asbestinins but will not cover efforts toward the total synthesis of the sarcodictyins. Eunicellin was the first reported member of the C2-C11 cyclized cembranoid natural products, isolated in 1968 by Djerassi and co-workers from the soft coral Eunicella stricta found off the coast of Banyuls-sur-Mer in France. Since this discovery, over 100 unique secondary metabolites of gorgonian octocorals have been characterized, including the first asbestinin in 1980 and the first briarellin in 1995. A wide range of structural diversity is displayed by this group of marine natural products. The natural role of these cembranoids is proposed, based upon mollusk and fish lethality assays, to involve predation deterrence. Upon further investigation, several of the members of these subclasses have demonstrated significant pharmacological potential. Particularly, these diterpenes have been shown to exhibit in vitro cytotoxicity against various cancer cell lines, anti-inflammatory properties, antimicrobial activities, and histamine and acetylcholine antagonism. The fascinating molecular architecture of these cembranoids, as well as their potential as therapeutic agents, has sparked much interest in the synthetic community over the past decade. A variety of approaches toward these challenging structural motifs have been investigated and several total syntheses have been accomplished. Efforts toward the total synthesis of the cladiellins, briarellins, and asbestinins are the subject of this review.

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