English

Active learning for energy-based antibody optimization and enhanced screening

Biomolecules 2024-09-19 v2 Artificial Intelligence Machine Learning Quantitative Methods

Abstract

Accurate prediction and optimization of protein-protein binding affinity is crucial for therapeutic antibody development. Although machine learning-based prediction methods ΔΔG\Delta\Delta G are suitable for large-scale mutant screening, they struggle to predict the effects of multiple mutations for targets without existing binders. Energy function-based methods, though more accurate, are time consuming and not ideal for large-scale screening. To address this, we propose an active learning workflow that efficiently trains a deep learning model to learn energy functions for specific targets, combining the advantages of both approaches. Our method integrates the RDE-Network deep learning model with Rosetta's energy function-based Flex ddG to efficiently explore mutants. In a case study targeting HER2-binding Trastuzumab mutants, our approach significantly improved the screening performance over random selection and demonstrated the ability to identify mutants with better binding properties without experimental ΔΔG\Delta\Delta G data. This workflow advances computational antibody design by combining machine learning, physics-based computations, and active learning to achieve more efficient antibody development.

Keywords

Cite

@article{arxiv.2409.10964,
  title  = {Active learning for energy-based antibody optimization and enhanced screening},
  author = {Kairi Furui and Masahito Ohue},
  journal= {arXiv preprint arXiv:2409.10964},
  year   = {2024}
}

Comments

8 pages

R2 v1 2026-06-28T18:47:29.874Z