Active learning for energy-based antibody optimization and enhanced screening

Kairi Furui, Masahito Ohue
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Abstract

Accurate prediction and optimization of protein-protein binding affinity is crucial for therapeutic antibody development. Although machine learning-based prediction methods $\Delta\Delta G$ 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 that bind to Flex ddG. 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 $\Delta\Delta G$ data. This workflow advances computational antibody design by combining machine learning, physics-based computations, and active learning to achieve more efficient antibody development.
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基于能量的抗体优化和增强筛选的主动学习
准确预测和优化蛋白质与蛋白质之间的结合亲和力对于治疗性抗体的开发至关重要。虽然基于机器学习的预测方法适用于大规模突变筛选,但它们很难预测多种突变对没有现有结合体的靶点的影响。基于能量函数的方法虽然更准确,但耗时长,并不适合大规模筛选。为了解决这个问题,我们提出了一种主动学习工作流程,它能有效地训练深度学习模型来学习特定靶标的能量函数,同时结合了这两种方法的优点。我们的方法将 RDE-Network 深度学习模型与 Rosetta 基于能量函数的 Flex ddG 整合在一起,高效地探索与 Flex ddG 结合的突变体。在一项针对与 HER2 结合的曲妥珠单抗突变体的案例研究中,与随机选择相比,我们的方法显著提高了筛选性能,并证明了在没有实验数据的情况下识别出具有更好结合特性的突变体的能力。该工作流程将机器学习、物理计算和主动学习相结合,实现了更高效的抗体开发,从而推动了计算抗体设计的发展。
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