Stellabody: A novel hexamer-promoting mutation for improved IgG potency.

IF 7.5 2区 医学 Q1 IMMUNOLOGY
Clarissa A Whitehead, Bruce D Wines, Anna M Davies, James M McDonnell, Halina M Trist, Sandra E Esparon, P Mark Hogarth
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引用次数: 0

Abstract

Advances in antibody engineering are being directed at the development of next generation immunotherapeutics with improved potency. Hexamerisation of IgG is a normal physiological aspect of IgG biology and recently described mutations that facilitate this process have a substantial impact upon monoclonal antibody behavior resulting in the elicitation of dramatically enhanced complement-dependent cytotoxicity, Fc receptor function, and enhanced antigen binding effects, such as targeted receptor agonism or microbe neutralization. Whereas the discovery of IgG hexamerisation enhancing mutations has largely focused on residues with exposure at the surface of the Fc-Fc and CH2-CH3 interfaces, our unique approach is the engineering of the mostly buried residue H429 in the CH3 domain. Selective substitution at position 429 forms the basis of Stellabody technology, where the choice of amino acid results in distinct hexamerisation outcomes. H429F results in monomeric IgG that hexamerises after target binding, so called "on-target" hexamerisation, while the H429Y mutant forms pH-sensitive hexamers in-solution prior to antigen binding. Moreover, Stellabody technologies are broadly applicable across the family of antibody-based biologic therapeutics, including conventional mAbs, bispecific mAbs, and Ig-like biologics such as Fc-fusions, with applications in diverse diseases.

Stellabody:一种新型六聚体促进突变,可提高 IgG 的效力。
抗体工程的进步旨在开发出效力更强的下一代免疫疗法。IgG 的六聚化是 IgG 生物学的一个正常生理方面,最近描述的突变促进了这一过程,对单克隆抗体的行为产生了重大影响,导致补体依赖性细胞毒性、Fc 受体功能和抗原结合效应(如靶向受体激动或微生物中和)显著增强。IgG六聚化增强突变的发现主要集中在Fc-Fc和CH2-CH3界面表面暴露的残基上,而我们的独特方法是对CH3结构域中大部分被埋藏的残基H429进行工程化。第 429 位的选择性取代构成了 Stellabody 技术的基础,氨基酸的选择会导致不同的六聚体化结果。H429F 导致单体 IgG 在目标结合后产生六聚体,即所谓的 "目标 "六聚体化,而 H429Y 突变体则在抗原结合前在溶液中形成 pH 敏感的六聚体。此外,Stellabody 技术广泛适用于各种基于抗体的生物疗法,包括传统 mAbs、双特异性 mAbs 和 Ig 类生物制剂(如 Fc 融合剂),可应用于多种疾病。
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来源期刊
Immunological Reviews
Immunological Reviews 医学-免疫学
CiteScore
16.20
自引率
1.10%
发文量
118
审稿时长
4-8 weeks
期刊介绍: Immunological Reviews is a specialized journal that focuses on various aspects of immunological research. It encompasses a wide range of topics, such as clinical immunology, experimental immunology, and investigations related to allergy and the immune system. The journal follows a unique approach where each volume is dedicated solely to a specific area of immunological research. However, collectively, these volumes aim to offer an extensive and up-to-date overview of the latest advancements in basic immunology and their practical implications in clinical settings.
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