Syntheses of Gabosine A, B, D, and E from Allyl Sulfide Derived from(-)-Quinic Acid

Tetsuro  Shinada; Toshiyuki  Fuji; Yasuhiro  Ohtani; Yasutaka  Yoshida; Yasufumi  Ohfune

doi:10.1055/s-2002-32985

LETTER

Syntheses of Gabosine A, B, D, and E from Allyl Sulfide Derived from(-)-Quinic Acid

Tetsuro Shinada*, Toshiyuki Fuji, Yasuhiro Ohtani, Yasutaka Yoshida, Yasufumi Ohfune*
Graduate School of Science, Osaka City University, Sugimoto, Sumiyoshi, Osaka 558-8585, Japan
Fax: +81(6)66053153; e-Mail: shinada@sci.osaka-cu.ac.jp; e-Mail: ohfune@sci.osaka-cu.ac.jp;

Abstract

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Abstract

An efficient conversion of allyl sulfide 6 prepared from (-)-quinic acid (5) to gabosines was achieved by a series of sequential reactions: i) Mislow-Evans rearrangement, ii) SeO₂ oxidation, iii) conjugate addition of sodium hydroxide or sodium acetate, and iv) elimination of the methoxymethyloxy group.

Key words

gabosine - cyclitol - allyl sulfide - quinic acid - conjugate addition

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References

Isolation and biological activity of gabosines:

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For recent synthetic studies:

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3b

The allyl sulfide can be prepared in a large scale (>20 g) from (-)-quinic acid via tributylphosphine-diphenyl disulfide-assisted regioselective dehydration and phenylthiolation of an exomethylene 1,2-diol intermediate.

4 For a review: Evans DA. Andrews GC. Acc. Chem. Res. 1974, 7: 147

5 It was presumed that the allylic oxidation of A would facilitate its conversion to B in comparison with that from 6 or 8 according to the related example: Bamba M. Nishikawa T. Isobe M. Synlett 1998, 371

6

The exclusive diastereofacial rearrangement would be induced by the steric repulsion of the bulky allylic silyloxy group which lies on the α-face of the cyclohexane ring.

7

Structures of 9, 11a, and 11b were confirmed by their conversions into conduritols A and C. Full details of these results will be reported in due course.

8 Kiegiel J. Wovkulich PM. Uskokovic MR. Tetrahedron Lett. 1991, 32: 6057

9 Albright JD. Goldman L. J. Am. Chem. Soc. 1967, 89: 2416

10

Yields on the deprotection step to gabosines were good to moderate (>59%) due probably to the prolonged reaction period leading to the undesired acid-catalyzed decomposition.