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Auteurs principaux: Chen, Jingke, Zhong, Jingrui, Tani, Tazneen Hossain, Su, Zidong, Zhang, Xiaochun, Tian, Boxue
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2604.16550
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author Chen, Jingke
Zhong, Jingrui
Tani, Tazneen Hossain
Su, Zidong
Zhang, Xiaochun
Tian, Boxue
author_facet Chen, Jingke
Zhong, Jingrui
Tani, Tazneen Hossain
Su, Zidong
Zhang, Xiaochun
Tian, Boxue
contents Despite the high accuracy of 'black box' deep learning models, drug discovery still relies on protein-ligand interaction principles and heuristics. To improve interpretability of protein-small molecule binding predictions, we developed the PWRules framework, which applies binding affinity data to identify privileged small molecule fragments and subsequently defines complementary pairing rules between these fragments and protein words (semantic sequence units) through an interpretability module. The resulting word-fragment rules are then ranked by the PWScore function to prioritize active compounds. Evaluations on benchmark datasets show that PWScore achieves competitive performance comparable to the physics-based model (Glide) and the deep learning model (PSICHIC) and shows broad applicability for protein targets outside the training dataset, e.g., SARS-CoV-2 main protease. Notably, PWScore captures complementary interaction information, yielding superior enrichment performance when integrated with these established methods. Structural analysis of protein-ligand complexes indicates that learned word-fragment rules are significantly enriched near ligand-binding pockets, despite training without explicit structural guidance. By extracting and applying complementary pairing rules, PWRules provides an interpretable framework for drug discovery.
format Preprint
id arxiv_https___arxiv_org_abs_2604_16550
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle An Interpretable Framework Applying Protein Words to Predict Protein-Small Molecule Complementary Pairing Rules
Chen, Jingke
Zhong, Jingrui
Tani, Tazneen Hossain
Su, Zidong
Zhang, Xiaochun
Tian, Boxue
Machine Learning
Artificial Intelligence
Despite the high accuracy of 'black box' deep learning models, drug discovery still relies on protein-ligand interaction principles and heuristics. To improve interpretability of protein-small molecule binding predictions, we developed the PWRules framework, which applies binding affinity data to identify privileged small molecule fragments and subsequently defines complementary pairing rules between these fragments and protein words (semantic sequence units) through an interpretability module. The resulting word-fragment rules are then ranked by the PWScore function to prioritize active compounds. Evaluations on benchmark datasets show that PWScore achieves competitive performance comparable to the physics-based model (Glide) and the deep learning model (PSICHIC) and shows broad applicability for protein targets outside the training dataset, e.g., SARS-CoV-2 main protease. Notably, PWScore captures complementary interaction information, yielding superior enrichment performance when integrated with these established methods. Structural analysis of protein-ligand complexes indicates that learned word-fragment rules are significantly enriched near ligand-binding pockets, despite training without explicit structural guidance. By extracting and applying complementary pairing rules, PWRules provides an interpretable framework for drug discovery.
title An Interpretable Framework Applying Protein Words to Predict Protein-Small Molecule Complementary Pairing Rules
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2604.16550