Overcoming a species-specificity barrier in development of an inhibitory antibody targeting a modulator of tumor stroma

I. Grossman, T. Ilani, S. Fleishman, D. Fass
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引用次数: 11

Abstract

The secreted disulfide catalyst Quiescin sulfhydryl oxidase-1 (QSOX1) affects extracellular matrix organization and is overexpressed in various adenocarcinomas and associated stroma. Inhibition of extracellular human QSOX1 by a monoclonal antibody decreased tumor cell migration in a cell co-culture model and hence may have therapeutic potential. However, the species specificity of the QSOX1 monoclonal antibody has been a setback in assessing its utility as an anti-metastatic agent in vivo, a common problem in the antibody therapy industry. We therefore used structurally guided engineering to expand the antibody species specificity, improving its affinity toward mouse QSOX1 by at least four orders of magnitude. A crystal structure of the re-engineered variant, complexed with its mouse antigen, revealed that the antibody accomplishes dual-species targeting through altered contacts between its heavy and light chains, plus replacement of bulky aromatics by flexible side chains and versatile water-bridged polar interactions. In parallel, we produced a surrogate antibody targeting mouse QSOX1 that exhibits a new QSOX1 inhibition mode. This set of three QSOX1 inhibitory antibodies is compatible with various mouse models for pre-clinical trials and biotechnological applications. In this study we provide insights into structural blocks to cross-reactivity and set up guideposts for successful antibody design and re-engineering.
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在肿瘤基质调节剂的抑制抗体开发中克服物种特异性障碍
分泌的二硫催化剂Quiescin巯基氧化酶-1 (QSOX1)影响细胞外基质组织,并在各种腺癌和相关基质中过表达。在细胞共培养模型中,单克隆抗体抑制细胞外的人QSOX1可减少肿瘤细胞的迁移,因此可能具有治疗潜力。然而,QSOX1单克隆抗体的物种特异性一直是评估其作为体内抗转移剂效用的一个挫折,这是抗体治疗行业的一个常见问题。因此,我们使用结构引导工程来扩大抗体的物种特异性,将其对小鼠QSOX1的亲和力提高了至少四个数量级。重组变体的晶体结构与小鼠抗原的复合物表明,该抗体通过改变其重链和轻链之间的接触,以及用灵活的侧链和多功能的水桥极性相互作用取代庞大的芳烃来实现双物种靶向。同时,我们制作了一种针对小鼠QSOX1的替代抗体,该抗体显示出新的QSOX1抑制模式。这组三种QSOX1抑制抗体与多种小鼠模型兼容,可用于临床前试验和生物技术应用。在这项研究中,我们提供了对交叉反应的结构块的见解,并为成功的抗体设计和重组建立了指南。
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