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Synlett 2022; 33(13): 1209-1214
DOI: 10.1055/a-1856-7334
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Syntheses of Aristotelia Alkaloids: Reflections in the Chiral Pool

Malaika D. Argade
,
Andrew P. Riley
We gratefully acknowledge startup funds provided by the University of Illinois at Chicago that provided funding for this work. Additional support was provided to A.P.R. by the National Institutes of Health, UIC Clinical and Translational Science Scholars Program (KL2TR0020002).
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Abstract

The Aristotelia alkaloids are a family of monoterpene indole alkaloids possessing a characteristic azabicyclononane scaffold, which has been assembled by several synthetic methods. Herein we review those approaches that have adopted a biomimetic approach to unite heterocyclic synthons with chiral-pool monoterpenes. Throughout this discussion, the tendency of monoterpenes like α-pinene and limonene to undergo racemization is highlighted, revealing the challenges in developing stereospecific syntheses of these alkaloids. Finally, we provide a brief discussion of how these synthetic efforts have enabled the structural confirmation and elucidation of the Aristotelia alkaloids’ absolute configurations, including our own recent efforts to employ bioactivity data to deduce the naturally occurring configuration of the quinoline alkaloid aristoquinoline.

1 Introduction

2 Mercury-Mediated Ritter-Like Reactions

3 Brønsted Acid Mediated Ritter-Like Reactions

4 Synthesis of Aristoquinoline: Ritter-Like Reaction Approach

5 Aza-Prins-Type Reaction in the Synthesis of Aristotelia Alkaloids

6 Determination of Naturally Occurring Absolute Stereochemistry

7 Conclusions

Key words

alkaloids - chiral pool - Ritter reaction - aza-Prins reaction - biomimetic synthesis


Publication History

Received: 05 May 2022

Accepted after revision: 19 May 2022

Accepted Manuscript online:
19 May 2022

Article published online:
15 June 2022

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