An enantioselective and modular platform for C4ʹ-modified nucleoside analogue synthesis enabled by intramolecular trans-acetalizations

Thirupathi Nuligonda; Gautam Kumar; Jason W. Wang; Dinithi Rajapaksha; Ismael A. Elayan; Ramiz Demir; Neil J. Meanwell; Sherrie F. Wang; Lara K. Mahal; Alex Brown; Michael W. Meanwell

doi:10.1038/s41467-024-51520-5

Nature Communications (Aug 2024)

An enantioselective and modular platform for C4ʹ-modified nucleoside analogue synthesis enabled by intramolecular trans-acetalizations

Thirupathi Nuligonda,
Gautam Kumar,
Jason W. Wang,
Dinithi Rajapaksha,
Ismael A. Elayan,
Ramiz Demir,
Neil J. Meanwell,
Sherrie F. Wang,
Lara K. Mahal,
Alex Brown,
Michael W. Meanwell

Affiliations

Thirupathi Nuligonda: Department of Chemistry, University of Alberta
Gautam Kumar: Department of Chemistry, University of Alberta
Jason W. Wang: Department of Chemistry, University of Alberta
Dinithi Rajapaksha: Department of Chemistry, University of Alberta
Ismael A. Elayan: Department of Chemistry, University of Alberta
Ramiz Demir: Department of Chemistry, University of Alberta
Neil J. Meanwell: Department of Chemistry, University of Alberta
Sherrie F. Wang: Department of Mathematics & Science, North Island College
Lara K. Mahal: Department of Chemistry, University of Alberta
Alex Brown: Department of Chemistry, University of Alberta
Michael W. Meanwell: Department of Chemistry, University of Alberta

DOI: https://doi.org/10.1038/s41467-024-51520-5
Journal volume & issue: Vol. 15, no. 1
pp. 1 – 7

Abstract

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Abstract C4ʹ-modified nucleoside analogues continue to attract global attention for their use in antiviral drug development and oligonucleotide-based therapeutics. However, current approaches to C4ʹ-modified nucleoside analogues still involve lengthy (9–16 steps), non-modular routes that are unamenable to library synthesis. Towards addressing the challenges associated with their syntheses, we report a modular 5-step process to a diverse collection of C4ʹ-modified nucleoside analogues through a sequence of intramolecular trans-acetalizations of readily assembled polyhydroxylated frameworks. Overall, the 2–3 fold reduction in step-count compares favorably to even recently reported biocatalytic approaches and should ultimately enable new opportunities in drug design around this popular chemotype.

Published in Nature Communications

ISSN: 2041-1723 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science
Website: https://www.nature.com/ncomms/

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