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Frustration in the protein-protein interface plays a central role in the cooperativity of PROTAC ternary complexes

Ning Ma, S. Bhattacharya, Sanychen Muk, Zuzana Jandová, Philipp S. Schmalhorst, Soumadwip Ghosh, Keith Le, Emelyne Diers, Nicole Trainor, William Farnaby, Michael J. Roy, Christiane Kofink, Peter Greb, Harald Weinstabl, Alessio Ciulli, Gerd Bader, Kyra Sankar, Andreas Bergner, Nagarajan Vaidehi

2025Nature Communications13 citationsDOIOpen Access PDF

Abstract

Targeted protein degradation using proteolysis-targeting chimeras (PROTACs) offers a promising strategy to eliminate previously undruggable proteins. PROTACs are bifunctional molecules that link a target protein with an E3 ubiquitin ligase, enabling the formation of a ternary complex that promotes ubiquitination and subsequent proteasomal degradation. Although many ternary complex structures are available, understanding how structural features relate to PROTAC function remains challenging due to the dynamic nature of these complexes. Here we show that the interface between the target protein SMARCA2 and the E3 ligase VHL is conformationally flexible and stabilized by interactions involving disordered loops. Using molecular dynamics simulations and X-ray crystallography of SMARCA2-VHL complexes bound to five different PROTACs, we find that interfacial residues often adopt energetically suboptimal, or 'frustrated,' configurations. We further show that the degree of frustration correlates with experimentally measured cooperativity for a set of 11 PROTACs. These findings suggest that quantifying interface frustration provides a rational, structure-based approach to guiding PROTAC design.

Topics & Concepts

CooperativityFrustrationTernary operationTernary complexBifunctionalUbiquitin ligaseUbiquitinChemistryCrystallographyChemical physicsBiophysicsFunction (biology)Protein functionCooperative bindingMolecular dynamicsPlasma protein bindingProtein degradationProtein structureInterface (matter)DNA ligaseProtein–protein interactionMoleculeMechanism (biology)Topology (electrical circuits)Materials scienceDegradation (telecommunications)NanotechnologyAllosteric regulationComputational biologyProtein Degradation and InhibitorsUbiquitin and proteasome pathwaysCancer-related gene regulation