Unified strategy for synthesis of indole and 2-oxindole alkaloids

Article abstract of DOI:10.1021/ja00016a036

A concise and general entry to representative indole alkaloids of the yohimboid, heteroyohimboid, corynantheoid, and 2-oxindole classes has been developed exploiting a strategy that features intramolecular Diels-Alder reactions for the facile construction of the D/E ring subunits of the target alkaloids. The efficacy of the approach is first illustrated by a two-step total synthesis of the yohimboid alkaloid oxogambirtannine (2) from 22. Thus, the Diels-Alder substrate 25, which was prepared by nucleophilic addition of vinyl ketene acetal 24 to the intermediate N-acyliminium salt formed in situ upon reaction of 22 with 23, was heated in the presence of benzoquinone to give a mixture of diastereoisomeric cycloadducts 26 and 27; these adducts underwent spontaneous oxidation to furnish 2. In another application of the strategy, the [4+2] heterocyclization of 34a, which was formed upon nucleophilic addition of 1-[(trimethylsilyl)oxy]butadiene to the N-acyliminium salt generated in situ upon treatment of 22 with crotonyl chloride, afforded a mixture (ca. 9:1) of cycloadducts 35a and 36a. The major adduct 35a was converted to 42a using a general procedure for effecting β-carbomethoxylation of enol ethers to give vinylogous carbonates. Subsequent reduction of 42a to the heteroyohimboid alkaloids (±)-tetrahydroalstonine (3) and (±)-cathenamine (4) was achieved by selective delivery of 2 or 1 equiv of hydride, respectively. When 42a was treated with sodium amide, stereoselective β-elimination ensued to give 49, which was converted by chemoselective hydride reduction into the corynantheoid alkaloid (±)-geissoschizine (5). Facile access to alkaloids of the 2-oxindole family was realized by using a new protocol for achieving stereoselective, oxidative rearrangements of β-carboline N_b lactams into 3,3-disubstituted 2-oxindoles. Thus, exposure of 42a to tert-butyl hypochlorite followed by acid and silver ion induced rearrangement of the intermediate 3-chloroindolenine gave 50, with only traces of the C(7) epimer being detected. Hydride reduction of 50 gave (±)-isopteropodine (6), acid-catalyzed isomerization of which furnished an equilibrium mixture (1:3) of 6 and (±)-pteropodine (51). The stereochemical course of the intramolecular hetero-Diels-Alder reaction of 34a to give 35a and 36a as the only isolable cycloadducts was examined by computational analysis. The geometry of the six-atom transition state was established by semiempirical methods by using the standard closed-shell, restricted Hartree-Fock (RHF) version of the AM1 method. With use of this constrained geometry for the six-membered pericyclic array, the overall conformational energies for the four possible transition states 52-55 were minimized by MM2 calculations (MacroModel). The calculated relative energies of these transition states were in the order 52 < 53 < 54 < 55. Since the cyclization of 34a produced only 35a and 36a in an approximately 9:1 ratio via the respective transition states 52 and 53, these calculations correlated qualitatively with the experimental results.