Abstract
Nature evolves molecular interaction networks through persistent perturbation and selection, in stark contrast to drug discovery, which evaluates candidates one at a time by screening. Here, nature's highly parallel ligand-target search paradigm is recapitulated in a screen of a DNA-encoded library (DEL; 73,728 ligands) against a library of RNA structures (4,096 targets). In total, the screen evaluated ∼300 million interactions and identified numerous bona fide ligand-RNA three-dimensional fold target pairs. One of the discovered ligands bound a 5'GAG/3'CCC internal loop that is present in primary microRNA-27a (pri-miR-27a), the oncogenic precursor of microRNA-27a. The DEL-derived pri-miR-27a ligand was cell active, potently and selectively inhibiting pri-miR-27a processing to reprogram gene expression and halt an otherwise invasive phenotype in triple-negative breast cancer cells. By exploiting evolutionary principles at the earliest stages of drug discovery, it is possible to identify high-affinity and selective target-ligand interactions and predict engagements in cells that short circuit disease pathways in preclinical disease models.
Keywords:
RNA; RNA folding; drug design; nucleic acids.
Copyright © 2022 the Author(s). Published by PNAS.
Publication types
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Research Support, N.I.H., Extramural
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Research Support, Non-U.S. Gov't
MeSH terms
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Carcinogenesis / drug effects
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Carcinogenesis / genetics
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Cell Line, Tumor
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Cell Proliferation / genetics
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DNA / genetics*
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Drug Discovery / methods
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Gene Expression / genetics
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Gene Library
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Humans
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Ligands
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MicroRNAs / genetics
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Oncogenes / genetics
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RNA, Untranslated / genetics*
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Small Molecule Libraries / pharmacology
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Triple Negative Breast Neoplasms / drug therapy
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Triple Negative Breast Neoplasms / genetics
Substances
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Ligands
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MicroRNAs
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RNA, Untranslated
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Small Molecule Libraries
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DNA