DNA-templated Organic Synthesis and Selection of a Library of Macrocycles

Overview

Journal Science

Specialty Science

Date 2004 Aug 21

PMID 15319493

Citations 120

Authors

Zev J Gartner

Brian N Tse

Rozalina Grubina

Jeffrey B Doyon

Thomas M Snyder

David R Liu

Affiliations

Soon will be listed here.

Abstract

The translation of nucleic acid libraries into corresponding synthetic compounds would enable selection and amplification principles to be applied to man-made molecules. We used multistep DNA-templated organic synthesis to translate libraries of DNA sequences, each containing three "codons," into libraries of sequence-programmed synthetic small-molecule macrocycles. The resulting DNA-macrocycle conjugates were subjected to in vitro selections for protein affinity. The identity of a single macrocycle possessing known target protein affinity was inferred through the sequence of the amplified DNA template surviving the selection. This work represents the translation, selection, and amplification of libraries of nucleic acids encoding synthetic small molecules rather than biological macromolecules.

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