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arxiv: 2410.09667 · v2 · pith:NBP2NUZSnew · submitted 2024-10-12 · 💻 cs.LG · physics.chem-ph· q-bio.BM

EquiJump: Protein Dynamics Simulation via SO(3)-Equivariant Stochastic Interpolants

classification 💻 cs.LG physics.chem-phq-bio.BM
keywords dynamicssimulationequijumpproteinproteinsdataenablesequivariant
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Mapping the conformational dynamics of proteins is crucial for elucidating their functional mechanisms. While Molecular Dynamics (MD) simulation enables detailed time evolution of protein motion, its computational toll hinders its use in practice. To address this challenge, multiple deep learning models for reproducing and accelerating MD have been proposed drawing on transport-based generative methods. However, existing work focuses on generation through transport of samples from prior distributions, that can often be distant from the data manifold. The recently proposed framework of stochastic interpolants, instead, enables transport between arbitrary distribution endpoints. Building upon this work, we introduce EquiJump, a transferable SO(3)-equivariant model that bridges all-atom protein dynamics simulation time steps directly. Our approach unifies diverse sampling methods and is benchmarked against existing models on trajectory data of fast folding proteins. EquiJump achieves state-of-the-art results on dynamics simulation with a transferable model on all of the fast folding proteins.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Learning Structure, Energy, and Dynamics: A Survey of Artificial Intelligence for Protein Dynamics

    q-bio.BM 2026-04 unverdicted novelty 2.0

    A review summarizing AI techniques for protein conformation generation, trajectory modeling, Boltzmann generators, machine learning potentials, and related challenges in scalability and physical consistency.