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Abstract Targeted protein degradation (TPD) is a powerful strategy for targeting and eliminating disease-causing proteins. While heterobifunctional Proteolysis-Targeting Chimeras (PROTACs) are more modular, the rational design of monovalent or molecular glue degraders remains challenging. In this study, we generated a small library of BET-domain inhibitor JQ1 analogs bearing elaborated electrophilic handles to identify permissive covalent degradative handles and E3 ligase pairs. We identified an elaborated fumaramide handle that, when appended onto JQ1, led to the proteasome-dependent degradation of BRD4. Further characterization revealed that the E3 ubiquitin ligase CUL4DCAF16—a common E3 ligase target of electrophilic degraders—was responsible for BRD4 loss by covalently targeting C173 on DCAF16. While this original fumaramide handle, when appended onto other protein-targeting ligands, did not accommodate the degradation of other neo-substrates, a truncated version of this handle attached to JQ1 was still capable of degrading BRD4, now through targeting both C173 and C178. This truncated fumaramide handle, when appended on various protein targeting ligands, and was also more permissive in degrading other neo-substrates, including CDK4/6, SMARCA2/4, and the androgen receptor (AR). We further demonstrated that this optimized truncated fumaramide handle, when transplanted onto an AR DNA binding domain-targeting ligand, could degrade both AR and the undruggable truncation variant of AR, AR-V7, in androgen-independent prostate cancer cells in a DCAF16-dependent manner. Overall, we have identified a unique DCAF16-targeting covalent degradative handle that can be transplanted across several protein-targeting ligands to induce the degradation of their respective targets for the modular design of monovalent or bifunctional degraders.
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This content will become publicly available on December 21, 2025
An in-cell approach to evaluate E3 ligases for use in targeted protein degradation
Abstract One of the major challenges in evaluating the suitability of potential ∼700 E3 ligases for target protein degradation (TPD) is the lack of binders specific to each E3 ligase. Here we apply genetic code expansion (GCE) to encode a tetrazine-containing non-canonical amino acid (Tet-ncAA) site-specifically into the E3 ligase, which can be conjugated with strained trans-cyclooctene (sTCO) tethered to a neo-substrate protein binder by click chemistry within living cells. The resulting E3 ligase minimally modified and functionalized in an E3-ligand free (ELF) manner, can be evaluated for TPD of the neo-substrate. We demonstrate that CRBN encoded with clickable Tet-ncAA, either in the known immunomodulatory drug (IMiD)-binding pocket or across surface, can be covalently tethered to sTCO-linker-JQ1 and recruit BRD2/4 for CRBN mediated degradation, indicating the high plasticity of CRBN for TPD. The degradation efficiency is dependent on location of the Tet-ncAA encoding on CRBN as well as the length of the linker, showing the capability of this approach to map the surface of E3 ligase for identifying optimal TPD pockets. This ELF-degrader approach has the advantages of not only maintaining the native state of E3 ligase, but also allowing the interrogation of E3 ligases and target protein partners under intracellular conditions and can be applied to any known E3 ligase.
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- Award ID(s):
- 2054824
- PAR ID:
- 10595363
- Publisher / Repository:
- bioRxiv
- Date Published:
- Format(s):
- Medium: X
- Institution:
- bioRxiv
- Sponsoring Org:
- National Science Foundation
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