Template-Guided 3D Molecular Pose Generation via Flow Matching and Differentiable Optimization
Abstract
Predicting the 3D conformation of small molecules within protein binding sites is a key challenge in drug design. When a crystallized reference ligand (template) is available, it provides geometric priors that can guide 3D pose prediction. We present a two-stage method for ligand conformation generation guided by such templates. In the first stage, we introduce a molecular alignment approach based on flow-matching to generate 3D coordinates for the ligand, using the template structure as a reference. In the second stage, a differentiable pose optimization procedure refines this conformation based on shape and pharmacophore similarities, internal energy, and, optionally, the protein binding pocket. We introduce a new benchmark of ligand pairs co-crystallized with the same target to evaluate our approach and show that it outperforms standard docking tools and open-access alignment methods, especially in cases involving low similarity to the template or high ligand flexibility.
Cite
Text
Bergues et al. "Template-Guided 3D Molecular Pose Generation via Flow Matching and Differentiable Optimization." Advances in Neural Information Processing Systems, 2025.Markdown
[Bergues et al. "Template-Guided 3D Molecular Pose Generation via Flow Matching and Differentiable Optimization." Advances in Neural Information Processing Systems, 2025.](https://mlanthology.org/neurips/2025/bergues2025neurips-templateguided/)BibTeX
@inproceedings{bergues2025neurips-templateguided,
title = {{Template-Guided 3D Molecular Pose Generation via Flow Matching and Differentiable Optimization}},
author = {Bergues, Noémie and Carré, Arthur and Join-Lambert, Paul and Hoffmann, Brice and Blondel, Arnaud and Tajmouati, Hamza},
booktitle = {Advances in Neural Information Processing Systems},
year = {2025},
url = {https://mlanthology.org/neurips/2025/bergues2025neurips-templateguided/}
}