Chen, Shu-Yu, Solazzo, Riccardo and Riniker, Sereina (2026) Machine learning, docking, or physics for structure prediction of ligand-induced ternary complexes. Current opinion in structural biology, 97. p. 103217. ISSN 1879-033X

Abstract

Proteolysis-targeting chimeras (PROTACs) and molecular glues promote targeted protein degradation by recruiting an E3 ligase to proteins of interest (POIs). An accurate 3D structure of the ternary complex formed by E3 ligase, ligand, and POI is central to the rational design of degraders. Elucidating this structure with crystallography or cryo-EM can be challenging due to conformational flexibility, dynamic protein-protein interactions, and high-dimensional binding landscapes. To facilitate structure-based design in the absence of an experimental structure, computational approaches have been proposed: (i) multistep methods involving traditional docking pipelines, and (ii) single-step methods with deep learning models to directly predict the complex structure. Multistep methods are limited by sampling complexity, accurate input structures, scoring accuracy, and computational cost, while single-step methods are faster but are constrained by training-data scarcity. Here, we examine recent advances and emerging tools in modeling ternary complexes, critically discuss their predictive power and limitations, and highlight remaining challenges.

Item Type:	Article
Date Deposited:	14 Feb 2026 00:45
Last Modified:	14 Feb 2026 00:45
URI:	https://oak.novartis.com/id/eprint/58564