Institute for Research in Molecular Medicine (INFORMM), Universiti Sains Malaysia, Minden, Penang, Malaysia.
Mol Biotechnol. 2024 Apr;66(4):568-581. doi: 10.1007/s12033-023-00885-x. Epub 2023 Sep 24.
Since the advent of hybridoma technology in the year 1975, it took a decade to witness the first approved monoclonal antibody Orthoclone OKT39 (muromonab-CD3) in the year 1986. Since then, continuous strides have been made to engineer antibodies for specific desired effects. The engineering efforts were not confined to only the variable domains of the antibody but also included the fragment crystallizable (Fc) region that influences the immune response and serum half-life. Engineering of the Fc fragment would have a profound effect on the therapeutic dose, antibody-dependent cell-mediated cytotoxicity as well as antibody-dependent cellular phagocytosis. The integration of computational techniques into antibody engineering designs has allowed for the generation of testable hypotheses and guided the rational antibody design framework prior to further experimental evaluations. In this article, we discuss the recent works in the Fc-fused molecule design that involves computational techniques. We also summarize the usefulness of in silico techniques to aid Fc-fused molecule design and analysis for the therapeutics application.
自 1975 年杂交瘤技术问世以来,历经十年,于 1986 年迎来了首个获批的单克隆抗体 Orthoclone OKT39(鼠抗 CD3)。自此之后,人们不断致力于针对特定治疗效果来对抗体进行工程改造。工程改造不仅局限于抗体的可变区,还包括影响免疫反应和血清半衰期的片段结晶区(Fc 区)。Fc 片段的工程改造会对治疗剂量、抗体依赖的细胞介导的细胞毒性以及抗体依赖的细胞吞噬作用产生深远的影响。将计算技术融入抗体工程设计中,可以生成可测试的假说,并在进一步的实验评估之前指导合理的抗体设计框架。本文讨论了涉及计算技术的 Fc 融合分子设计的最新进展。我们还总结了计算技术在辅助 Fc 融合分子设计和分析中的应用,以实现治疗用途。
