Voacangalactone

Voacangalactone

Organic Letters 2012, 14, 5800

M. Harada, K. N. Asaba, M. Iwai, N. Kogure, M. Kitajima, and H. Takayama*

The retrosynthesis of Voacangalactone A begins with the reduction of keto-amide group in 17 to reveal the amine functionality.  Compound 17 was prepared by cyclization of the keto-ester on the deprotected amine, which in turn came by acylation of oxalyl chloride on indole 16.  The indole ring was closed by using Utimoto’s protocol employing NaAuCl₄.2H₂O as the oxidant on alkyne 15, which was prepared by a Sonogashira reaction between 2-iodo-4-methoxyaniline and alkyne 14.  Here, CuSO₄ was used as the copper source – no doubt reduced to Cu(I) by Na-ascorbate.  I had never seen being used in Sonogashira reaction, but this is referenced from the work of Bag, S. S. et al. Org. Chem. 2011, 76, 2332–2337.  Going further back, the alkyne 14 was prepared from alcohol 13 using standard transformations.  Compound 13’s precursor was iodo-alcohol 12, which came from acid 11.  Acid 11 was prepared by an iodo-lactonization-hydrolysis sequence on diester 10.  This is a really nice step as it establishes the lactone-ring elegantly and also allows differentiation of the oxidation states of the pendant carbon.  The bicyclic-amine 10 was closed by alkylating Cbz-amine 9.  Compound 9 is a penta-substituted cyclohexene and thus it is not surprising that an asymmetric Diels-Alder reaction was used to prepare it.  Its immediate precursor is the chiral auxiallary containing intermediate 8, which comes by a Diels-Alder reaction between dimethyl 2-methylenemalonate and diene 7.  This Diels-Alder reaction is between an electron-rich diene and an electron-deficient dienophile.  No wonder, it even goes at room temperature.  It is also completely regioselective – again due to the relative electronics of the reactants.  The absolute stereochemistry is driven by the chiral auxiallary.  This is the key step of this synthesis.  The diene was prepared by a Cu-mediated amination of vinyl-iodide 5.  Adjustment of the carbon oxidation states meant that 5 came from conjugated ester 4, which came from aldehyde 3 by a Wittig reaction.  Aldehyde 3 was prepared by reduction-oxidation sequence on acid 2, which was prepared by decarboxylation/hydrolysis of diester 1.  Diester 1 was prepared by alkylation of diethyl ethylmalonate.

 

Overall, a really nice synthesis.