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Correction to "Transcriptome-Wide Mapping of Small-Molecule RNA-Binding Sites in Cells Informs an Isoform-Specific Degrader of QSOX1 mRNA"
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Significance
The development of selective bioactive compounds that target RNA structures is difficult. Here we report an approach to identify low molecular weight fragments that bind to a cancer-causing RNA. By determining where the fragments bind within an RNA target, they can be assembled to provide a high-affinity and potent inhibitor. This approach could be a general way to develop bioactive small molecules that target RNA, which previously was considered “undruggable.” It was applied to provide a precision lead medicine against an RNA that contributes to cancer metastasis.
Advances in the synthesis and screening of small-molecule libraries have accelerated the discovery of chemical probes for studying biological processes. Still, only a small fraction of the human proteome has chemical ligands. Here, we describe a platform that marries fragment-based ligand discovery with quantitative chemical proteomics to map thousands of reversible small molecule-protein interactions directly in human cells, many of which can be site-specifically determined. We show that fragment hits can be advanced to furnish selective ligands that affect the activity of proteins heretofore lacking chemical probes. We further combine fragment-based chemical proteomics with phenotypic screening to identify small molecules that promote adipocyte differentiation by engaging the poorly characterized membrane protein PGRMC2. Fragment-based screening in human cells thus provides an extensive proteome-wide map of protein ligandability and facilitates the coordinated discovery of bioactive small molecules and their molecular targets.