AI Article Synopsis
- PROTACs are advanced tools in drug development that enable targeted protein degradation by utilizing a ligand for the target protein, a ligand for E3 ligase, and a connecting linker.
- Despite over 600 known E3 ligases, only a few are used in therapeutic applications due to limited available ligands and structural data complicating ligand design.
- This study aims to identify promising E3 ligases for development by using chemoproteomic data and AlphaFold models to evaluate ligandability, focusing on potentially reactive cysteines to enhance the PROTAC arsenal.
Article Abstract
Proteolysis Targeting Chimeras (PROTACs) are an emerging therapeutic modality and chemical biology tools for Targeted Protein Degradation (TPD). PROTACs contain a ligand targeting the protein of interest, a ligand recruiting an E3 ligase and a linker connecting these two ligands. There are over 600 E3 ligases known so far, but only a handful have been exploited for TPD applications. A key reason for this is the scarcity of ligands binding various E3 ligases and the paucity of structural data available, which complicates ligand design across the family. In this study, we aim to progress PROTAC discovery by proposing a shortlist of E3 ligases that can be prioritized for covalent targeting by performing systematic structural ligandability analysis on a chemoproteomic dataset of potentially reactive cysteines across hundreds of E3 ligases. One of the goals of this study is to apply AlphaFold (AF) models for ligandability evaluations, as for a vast majority of these ligases an experimental structure is not available in the protein data bank (PDB). Using a combination of pocket features, AF model quality and additional aspects, we propose a shortlist of E3 ligases and corresponding cysteines that can be prioritized to potentially discover covalent ligands and expand the PROTAC toolbox.
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| http://dx.doi.org/10.1002/prot.26675 | DOI Listing |
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