The Construction Strategy

The strategy for the construction of 13 from aldehyde 16 with two units of phosphonate 15 is summarized in Scheme 12. As expected, aldehyde 16 condenses smoothly with the anion derived from 15 to give, as the major product, the corresponding E,E,E-tri-ene ester. Reduction of the latter substance to the corresponding primary alcohol with Dibal-H, followed by oxidation with MnC>2, then furnishes aldehyde 60 in 86 % overall yield. Reiteration of this tactic and a simple deprotection step completes the synthesis of the desired intermediate 13 in good overall yield and with excellent stereoselectivity. 

Figure 1. Stereospecific [3,3]-Sigmatropic rearrangement strategy for the construction of ring B. R = Sif-BuMe2.

As attractive as the transannular bridging of bis(thiolactones) to bicyclic bis(oxepane) frameworks is, our inability to convert the disulfide bridging product (see 25, Scheme 5) to a mmv-fused bre-vetoxin-type bis(oxepane) (see 28) necessitated the development of a modified, stepwise strategy. This new stepwise approach actually comprises two very effective methods for the construction of cyclic ethers the first of these is the intramolecular photo-induced coupling of dithioesters, and the second is the reductive cyclization of hydroxy ketones. We will first address the important features of both cyclization strategies, and then show how the combination of the two can provide an effective solution to the problem posed by trans-fused bis(oxepanes). 

The reaction processes shown in Scheme 8 not only accomplish the construction of an oxepane system but also furnish a valuable keto function. The realization that this function could, in an appropriate setting, be used to achieve the annulation of the second oxepane ring led to the development of a new strategy for the synthesis of cyclic ethers the reductive cyclization of hydroxy ketones (see Schemes 9 and 10).23 The development of this strategy was inspired by the elegant work of Olah 24 the scenario depicted in Scheme 9 captures its key features. It was anticipated that activation of the Lewis-basic keto function in 43 with a Lewis acid, perhaps trimethylsilyl triflate, would induce nucleophilic attack by the proximal hydroxyl group to give an intermediate of the type 44. 

Having developed effective synthetic methodology for the construction of seven-membered cyclic ethers, we were confident that the problem of the frans-fused bis(oxepane) system could now be addressed on a solid foundation. It was our hope that the breve-toxin-type bis(oxepane) system could be assembled by a stepwise strategy utilizing both photochemical dithioester and reductive hydroxy ketone cyclization methods. 

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