Deciphering evolution of immune recognition in antibodies

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology BMC Structural Biology Pub Date : 2018-12-19 DOI:10.1186/s12900-018-0096-1
Harmeet Kaur, Neetu Sain, Debasisa Mohanty, Dinakar M. Salunke
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引用次数: 5

Abstract

Antibody, the primary effector molecule of the immune system, evolves after initial encounter with the antigen from a precursor form to a mature one to effectively deal with the antigen. Antibodies of a lineage diverge through antigen-directed isolated pathways of maturation to exhibit distinct recognition potential. In the context of evolution in immune recognition, diversity of antigen cannot be ignored. While there are reports on antibody lineage, structural perspective with respect to diverse recognition potential in a lineage has never been studied. Hence, it is crucial to evaluate how maturation leads to topological tailoring within a lineage enabling them to interact with significantly distinct antigens.

A data-driven approach was undertaken for the study. Global experimental mouse and human antibody-antigen complex structures from PDB were compiled into a coherent database of germline-linked antibodies bound with distinct antigens. Structural analysis of all lineages showed variations in CDRs of both H and L chains. Observations of conformational adaptation made from analysis of static structures were further evaluated by characterizing dynamics of interaction in two lineages, mouse VH1–84 and human VH5–51. Sequence and structure analysis of the lineages explained that somatic mutations altered the geometries of individual antibodies with common structural constraints in some CDRs. Additionally, conformational landscape obtained from molecular dynamics simulations revealed that incoming pathogen led to further conformational divergence in the paratope (as observed across datasets) even while maintaining similar overall backbone topology. MM-GB/SA analysis showed binding energies to be in physiological range. Results of the study are coherent with experimental observations.

The findings of this study highlight basic structural principles shaping the molecular evolution of a lineage for significantly diverse antigens. Antibodies of a lineage follow different developmental pathways while preserving the imprint of the germline. From the study, it can be generalized that structural diversification of the paratope is an outcome of natural selection of a conformation from an available ensemble, which is further optimized for antigen interaction. The study establishes that starting from a common lineage, antibodies can mature to recognize a wide range of antigens. This hypothesis can be further tested and validated experimentally.

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解读抗体免疫识别的进化
抗体是免疫系统的主要效应分子,在与抗原初次相遇后,由前体形态进化为成熟形态,从而有效地对抗抗原。一个谱系的抗体通过抗原导向的分离成熟途径分化,表现出不同的识别潜力。在免疫识别进化的背景下,抗原的多样性是不可忽视的。虽然有关于抗体谱系的报道,但从结构角度来看,在一个谱系中不同的识别潜力从未被研究过。因此,评估成熟如何导致谱系内的拓扑裁剪,使它们能够与显著不同的抗原相互作用是至关重要的。本研究采用数据驱动的方法。来自PDB的全球实验小鼠和人抗体-抗原复合物结构被编译成与不同抗原结合的种系连锁抗体的连贯数据库。所有谱系的结构分析显示H链和L链的cdr都存在差异。通过对小鼠VH1-84和人类VH5-51两个谱系相互作用的动力学特征,进一步评估了静态结构分析中观察到的构象适应。谱系的序列和结构分析解释了体细胞突变改变了一些cdr中具有共同结构限制的单个抗体的几何形状。此外,从分子动力学模拟中获得的构象景观显示,即使在保持相似的总体主干拓扑结构的情况下,传入的病原体也会导致副翼进一步的构象分化(正如在数据集中观察到的那样)。MM-GB/SA分析显示结合能在生理范围内。研究结果与实验结果一致。本研究的发现强调了基本的结构原则,塑造了一个谱系的分子进化显著不同的抗原。一个谱系的抗体遵循不同的发育途径,同时保留种系的印记。从研究中可以概括出,伞体的结构多样化是自然选择的结果,从一个可用的集合中选择一个构象,进一步优化抗原相互作用。这项研究表明,从一个共同的谱系开始,抗体可以成熟到识别各种抗原。这一假设可以通过实验进一步验证和验证。
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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
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0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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