Inference and design of antibody specificity: From experiments to models and back.

IF 3.8 2区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS PLoS Computational Biology Pub Date : 2024-10-14 eCollection Date: 2024-10-01 DOI:10.1371/journal.pcbi.1012522
Jorge Fernandez-de-Cossio-Diaz, Guido Uguzzoni, Kévin Ricard, Francesca Anselmi, Clément Nizak, Andrea Pagnani, Olivier Rivoire
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Abstract

Exquisite binding specificity is essential for many protein functions but is difficult to engineer. Many biotechnological or biomedical applications require the discrimination of very similar ligands, which poses the challenge of designing protein sequences with highly specific binding profiles. Experimental methods for generating specific binders rely on in vitro selection, which is limited in terms of library size and control over specificity profiles. Additional control was recently demonstrated through high-throughput sequencing and downstream computational analysis. Here we follow such an approach to demonstrate the design of specific antibodies beyond those probed experimentally. We do so in a context where very similar epitopes need to be discriminated, and where these epitopes cannot be experimentally dissociated from other epitopes present in the selection. Our approach involves the identification of different binding modes, each associated with a particular ligand against which the antibodies are either selected or not. Using data from phage display experiments, we show that the model successfully disentangles these modes, even when they are associated with chemically very similar ligands. Additionally, we demonstrate and validate experimentally the computational design of antibodies with customized specificity profiles, either with specific high affinity for a particular target ligand, or with cross-specificity for multiple target ligands. Overall, our results showcase the potential of leveraging a biophysical model learned from selections against multiple ligands to design proteins with tailored specificity, with applications to protein engineering extending beyond the design of antibodies.

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抗体特异性的推断与设计:从实验到模型再到实验
精湛的结合特异性对许多蛋白质功能至关重要,但却很难设计。许多生物技术或生物医学应用需要区分非常相似的配体,这给设计具有高度特异性结合特征的蛋白质序列带来了挑战。生成特异性结合体的实验方法依赖于体外选择,而体外选择在库规模和对特异性特征的控制方面受到限制。最近,通过高通量测序和下游计算分析,证明了更多的控制方法。在这里,我们采用这种方法展示了实验探究之外的特异性抗体设计。我们这样做的背景是需要区分非常相似的表位,而且这些表位无法通过实验与选择中存在的其他表位区分开来。我们的方法包括识别不同的结合模式,每种结合模式都与特定的配体有关,抗体要么被选择,要么不被选择。利用噬菌体展示实验的数据,我们表明该模型成功地将这些模式分离出来,即使它们与化学性质非常相似的配体相关联。此外,我们还通过实验证明并验证了计算设计的抗体具有定制的特异性特征,既可以对特定目标配体具有特异性高亲和力,也可以对多种目标配体具有交叉特异性。总之,我们的研究结果展示了利用从针对多种配体的选择中学到的生物物理模型来设计具有定制特异性的蛋白质的潜力,其在蛋白质工程中的应用已超出了抗体设计的范畴。
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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来源期刊
PLoS Computational Biology
PLoS Computational Biology BIOCHEMICAL RESEARCH METHODS-MATHEMATICAL & COMPUTATIONAL BIOLOGY
CiteScore
7.10
自引率
4.70%
发文量
820
审稿时长
2.5 months
期刊介绍: PLOS Computational Biology features works of exceptional significance that further our understanding of living systems at all scales—from molecules and cells, to patient populations and ecosystems—through the application of computational methods. Readers include life and computational scientists, who can take the important findings presented here to the next level of discovery. Research articles must be declared as belonging to a relevant section. More information about the sections can be found in the submission guidelines. Research articles should model aspects of biological systems, demonstrate both methodological and scientific novelty, and provide profound new biological insights. Generally, reliability and significance of biological discovery through computation should be validated and enriched by experimental studies. Inclusion of experimental validation is not required for publication, but should be referenced where possible. Inclusion of experimental validation of a modest biological discovery through computation does not render a manuscript suitable for PLOS Computational Biology. Research articles specifically designated as Methods papers should describe outstanding methods of exceptional importance that have been shown, or have the promise to provide new biological insights. The method must already be widely adopted, or have the promise of wide adoption by a broad community of users. Enhancements to existing published methods will only be considered if those enhancements bring exceptional new capabilities.
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