Adaption of human antibody λ and κ light chain architectures to CDR repertoires

R. van der Kant, Joschka Bauer, Anne R. Karow-Zwick, Sebastian Kube, P. Garidel, M. Blech, F. Rousseau, J. Schymkowitz
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引用次数: 10

Abstract

Abstract Monoclonal antibodies bind with high specificity to a wide range of diverse antigens, primarily mediated by their hypervariable complementarity determining regions (CDRs). The defined antigen binding loops are supported by the structurally conserved β-sandwich framework of the light chain (LC) and heavy chain (HC) variable regions. The LC genes are encoded by two separate loci, subdividing the entity of antibodies into kappa (LCκ) and lambda (LCλ) isotypes that exhibit distinct sequence and conformational preferences. In this work, a diverse set of techniques were employed including machine learning, force field analysis, statistical coupling analysis and mutual information analysis of a non-redundant antibody structure collection. Thereby, it was revealed how subtle changes between the structures of LCκ and LCλ isotypes increase the diversity of antibodies, extending the predetermined restrictions of the general antibody fold and expanding the diversity of antigen binding. Interestingly, it was found that the characteristic framework scaffolds of κ and λ are stabilized by diverse amino acid clusters that determine the interplay between the respective fold and the embedded CDR loops. In conclusion, this work reveals how antibodies use the remarkable plasticity of the beta-sandwich Ig fold to incorporate a large diversity of CDR loops.
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人抗体λ和κ轻链结构对CDR库的适应
单克隆抗体对多种抗原具有高特异性,主要由其高可变互补决定区(cdr)介导。确定的抗原结合环由轻链(LC)和重链(HC)可变区结构保守的β-三明治框架支持。LC基因由两个独立的基因座编码,将抗体实体细分为kappa (lκ)和lambda (lλ)同型,它们具有不同的序列和构象偏好。在这项工作中,采用了多种技术,包括机器学习,力场分析,统计耦合分析和非冗余抗体结构集合的互信息分析。由此,揭示了lκ和lλ同型结构之间的细微变化如何增加抗体的多样性,延长了一般抗体折叠的预定限制,扩大了抗原结合的多样性。有趣的是,发现κ和λ的特征框架支架被不同的氨基酸团稳定,这些氨基酸团确定了各自折叠与嵌入的CDR环之间的相互作用。总之,这项工作揭示了抗体如何利用β -三明治Ig折叠的显著可塑性来结合大量多样性的CDR环。
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