AbDPP:利用预培训和先前的生物结构知识进行目标导向型抗体设计。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-01 Epub Date: 2024-03-05 DOI:10.1002/prot.26676
Chenglei Yu, Xiangtian Lin, Yuxuan Cheng, Jiahong Xu, Hao Wang, Yuyao Yan, Yanting Huang, Lanxuan Liu, Wei Zhao, Qin Zhao, John Wang, Lei Zhang
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引用次数: 0

摘要

抗体是一类重要的复杂蛋白质疗法,对治疗多种人类疾病至关重要。传统的抗体发现方法,如杂交瘤和噬菌体展示技术,存在效率低、对潜在抗体的探索空间有限等局限性。为了克服这些局限性,我们提出了一种利用深度学习算法生成抗体序列的新方法,称为 AbDPP(具有预训练和先验生物学知识的目标导向抗体设计)。AbDPP 将预先训练好的抗体模型与生物区域信息整合在一起,能有效利用大量抗体序列数据和对复杂生物系统的理解来生成序列。针对特定的抗原,AbDPP 整合了抗体特性评估模型,并根据评估结果进一步优化,以生成更有针对性的序列。我们通过多项实验评估了 AbDPP 的功效,包括评估其生成氨基酸的能力、提高中和与结合的能力、保持序列一致性的能力以及提高序列多样性的能力。结果表明,AbDPP 在生成序列的性能和质量方面优于其他方法,展示了其在提高抗体设计和筛选效率方面的潜力。总之,这项研究为抗体生成领域提供了一种基于深度学习的创新方法,解决了传统方法的一些局限性,并强调了在生成新序列时整合特定抗体预训练模型和抗体生物学特性的重要性。本文的代码和文档可在 https://github.com/zlfyj/AbDPP 免费获取。
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AbDPP: Target-oriented antibody design with pretraining and prior biological structure knowledge.

Antibodies represent a crucial class of complex protein therapeutics and are essential in the treatment of a wide range of human diseases. Traditional antibody discovery methods, such as hybridoma and phage display technologies, suffer from limitations including inefficiency and a restricted exploration of the immense space of potential antibodies. To overcome these limitations, we propose a novel method for generating antibody sequences using deep learning algorithms called AbDPP (target-oriented antibody design with pretraining and prior biological knowledge). AbDPP integrates a pretrained model for antibodies with biological region information, enabling the effective use of vast antibody sequence data and intricate biological system understanding to generate sequences. To target specific antigens, AbDPP incorporates an antibody property evaluation model, which is further optimized based on evaluation results to generate more focused sequences. The efficacy of AbDPP was assessed through multiple experiments, evaluating its ability to generate amino acids, improve neutralization and binding, maintain sequence consistency, and improve sequence diversity. Results demonstrated that AbDPP outperformed other methods in terms of the performance and quality of generated sequences, showcasing its potential to enhance antibody design and screening efficiency. In summary, this study contributes to the field by offering an innovative deep learning-based method for antibody generation, addressing some limitations of traditional approaches, and underscoring the importance of integrating a specific antibody pretrained model and the biological properties of antibodies in generating novel sequences. The code and documentation underlying this article are freely available at https://github.com/zlfyj/AbDPP.

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CiteScore
7.20
自引率
4.30%
发文量
567
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