Using Pretrained Graph Neural Networks with Token Mixers As Geometric Featurizers for Conformational Dynamics

Overview

Journal J Chem Phys

Publisher American Institute of Physics

Date 2025 Jan 28

PMID 39873278

Authors

Zihan Pengmei

Chatipat Lorpaiboon

Spencer C Guo

Jonathan Weare

Aaron R Dinner

Affiliations

Soon will be listed here.

Abstract

Identifying informative low-dimensional features that characterize dynamics in molecular simulations remains a challenge, often requiring extensive manual tuning and system-specific knowledge. Here, we introduce geom2vec, in which pretrained graph neural networks (GNNs) are used as universal geometric featurizers. By pretraining equivariant GNNs on a large dataset of molecular conformations with a self-supervised denoising objective, we obtain transferable structural representations that are useful for learning conformational dynamics without further fine-tuning. We show how the learned GNN representations can capture interpretable relationships between structural units (tokens) by combining them with expressive token mixers. Importantly, decoupling training the GNNs from training for downstream tasks enables analysis of larger molecular graphs (that can represent small proteins at all-atom resolution) with limited computational resources. In these ways, geom2vec eliminates the need for manual feature selection and increases the robustness of simulation analyses.

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