3D Molecular Pretraining via Localized Geometric Generation

bioRxiv - Bioinformatics Pub Date : 2024-09-14 DOI:10.1101/2024.09.10.612249

Yuancheng Sun, Kai Chen, Kang Liu, Qiwei Ye

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Abstract

Self-supervised learning on 3D molecular structures is gaining importance in data-driven scientific research and applications due to the high costs of annotating biochemical data. However, the strategic selection of semantic units for modeling 3D molecular structures remains underexplored, despite its crucial role in effective pretraining - a concept well-established in language processing and computer vision. We introduce Localized Geometric Generation (LEGO), a novel approach that treats tetrahedrons within 3D molecular structures as fundamental building blocks, leveraging their geometric simplicity and widespread presence across chemical functional patterns. Inspired by masked modeling, LEGO perturbs tetrahedral local structures and learns to reconstruct them in a self-supervised manner. Experimental results demonstrate LEGO consistently enhances molecular representations across biochemistry and quantum property prediction benchmarks. Additionally, the tetrahedral modeling and pretraining generalize from small molecules to larger molecular systems, validating by protein-ligand affinity prediction. Our results highlight the potential of selecting semantic units to build more expressive and interpretable neural networks for scientific AI applications.

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通过局部几何生成进行三维分子预训练

由于生化数据注释成本高昂，三维分子结构的自监督学习在数据驱动的科学研究和应用中越来越重要。然而，用于三维分子结构建模的语义单元的战略选择仍未得到充分探索，尽管它在有效的预训练中起着至关重要的作用--这一概念在语言处理和计算机视觉领域已得到广泛认可。我们介绍了局部几何生成（LEGO），这是一种将三维分子结构中的四面体作为基本构件的新方法，充分利用了四面体的几何简洁性和在化学功能模式中的广泛存在。受遮蔽建模的启发，LEGO 会扰动四面体的局部结构，并学会以自我监督的方式重建它们。实验结果表明，在生物化学和量子特性预测基准中，乐高始终如一地增强了分子表征。此外，四面体建模和预训练可从小分子推广到更大的分子系统，并通过蛋白质配体亲和力预测得到验证。我们的研究结果凸显了选择语义单元为科学人工智能应用构建更具表现力和可解释性的神经网络的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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bioRxiv - Bioinformatics

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