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Main Authors: Liu, Yu, Wang, Ailun, Xia, Yu, Wang, Zhi, Yan, Wen
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.22274
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author Liu, Yu
Wang, Ailun
Xia, Yu
Wang, Zhi
Yan, Wen
author_facet Liu, Yu
Wang, Ailun
Xia, Yu
Wang, Zhi
Yan, Wen
contents Absolute binding free energy (ABFE) calculations offer a theoretically rigorous approach for predicting protein--ligand binding affinities without the scaffold constraints of relative binding free energy (RBFE) perturbations. However, broad adoption of ABFE in high-throughput hit discovery campaigns has been hindered by high computational costs and a lack of large-scale validation. Here, we present Felis, an open-source, automated, and scalable toolkit designed for high-throughput ABFE calculations. Paired with ByteFF, a previously developed data-driven molecular mechanics force field for drug-like molecules, Felis achieves ranking performance comparable to state-of-the-art RBFE methods on a diverse dataset comprising 43 protein targets and 859 ligands. Furthermore, we demonstrate robust convergence and ranking performance of Felis on a more challenging KRAS(G12D) dataset, where some ligands and the cofactor are highly charged. Crucially, all Felis predictions in this study were generated in a strict zero-shot manner, eschewing custom force-field modifications and alchemical schedule fine-tuning. This demonstrates the viability of Felis as an effective, ready-to-use tool for computational structure-based drug design.
format Preprint
id arxiv_https___arxiv_org_abs_2603_22274
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Development and large-scale benchmarks of a protein--ligand absolute binding free energy toolkit
Liu, Yu
Wang, Ailun
Xia, Yu
Wang, Zhi
Yan, Wen
Computational Physics
Absolute binding free energy (ABFE) calculations offer a theoretically rigorous approach for predicting protein--ligand binding affinities without the scaffold constraints of relative binding free energy (RBFE) perturbations. However, broad adoption of ABFE in high-throughput hit discovery campaigns has been hindered by high computational costs and a lack of large-scale validation. Here, we present Felis, an open-source, automated, and scalable toolkit designed for high-throughput ABFE calculations. Paired with ByteFF, a previously developed data-driven molecular mechanics force field for drug-like molecules, Felis achieves ranking performance comparable to state-of-the-art RBFE methods on a diverse dataset comprising 43 protein targets and 859 ligands. Furthermore, we demonstrate robust convergence and ranking performance of Felis on a more challenging KRAS(G12D) dataset, where some ligands and the cofactor are highly charged. Crucially, all Felis predictions in this study were generated in a strict zero-shot manner, eschewing custom force-field modifications and alchemical schedule fine-tuning. This demonstrates the viability of Felis as an effective, ready-to-use tool for computational structure-based drug design.
title Development and large-scale benchmarks of a protein--ligand absolute binding free energy toolkit
topic Computational Physics
url https://arxiv.org/abs/2603.22274