单克隆抗体作为加速靶点验证和可成药位点发现的工具性生物制剂。

Monobodies as tool biologics for accelerating target validation and druggable site discovery.

作者信息

Akkapeddi Padma, Teng Kai Wen, Koide Shohei

机构信息

Perlmutter Cancer Center, New York University Langone Medical Center New York NY USA

Department of Biochemistry and Molecular Pharmacology, New York University School of Medicine New York NY USA.

出版信息

RSC Med Chem. 2021 Sep 13;12(11):1839-1853. doi: 10.1039/d1md00188d. eCollection 2021 Nov 17.

DOI:10.1039/d1md00188d

PMID:34820623

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8597423/

Abstract

Despite increased investment and technological advancement, new drug approvals have not proportionally increased. Low drug approval rates, particularly for new targets, are linked to insufficient target validation at early stages. Thus, there remains a strong need for effective target validation techniques. Here, we review the use of synthetic binding proteins as tools for drug target validation, with focus on the monobody platform among several advanced synthetic binding protein platforms. Monobodies with high affinity and high selectivity can be rapidly developed against challenging targets, such as KRAS mutants, using protein engineering technologies. They have strong tendency to bind to functional sites and thus serve as drug-like molecules, and they can serve as targeting ligands for constructing bio-PROTACs. Genetically encoded monobodies are effective "tool biologics" for validating intracellular targets. They promote crystallization and help reveal the atomic structures of the monobody-target interface, which can inform drug design. Using case studies, we illustrate the potential of the monobody technology in accelerating target validation and small-molecule drug discovery.

摘要

尽管投资增加和技术进步，但新药获批数量并未相应增加。较低的药物获批率，尤其是针对新靶点的获批率，与早期靶点验证不足有关。因此，仍然迫切需要有效的靶点验证技术。在此，我们综述了合成结合蛋白作为药物靶点验证工具的应用，重点关注几种先进的合成结合蛋白平台中的单域抗体平台。利用蛋白质工程技术，可以快速开发出针对具有挑战性的靶点（如KRAS突变体）的具有高亲和力和高选择性的单域抗体。它们具有强烈的结合功能位点的倾向，因此可作为类药物分子，并且可以作为构建生物PROTAC的靶向配体。基因编码的单域抗体是用于验证细胞内靶点的有效的“工具生物制剂”。它们促进结晶并有助于揭示单域抗体-靶点界面的原子结构，这可为药物设计提供信息。通过案例研究，我们阐述了单域抗体技术在加速靶点验证和小分子药物发现方面的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e79b/8597423/036fe902eccb/d1md00188d-f1.jpg

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单克隆抗体作为加速靶点验证和可成药位点发现的工具性生物制剂。

Monobodies as tool biologics for accelerating target validation and druggable site discovery.

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