Discovery of a single-subunit oligosaccharyltransferase that enables glycosylation of full-length IgG antibodies in Escherichia coli

Belen Sotomayor, Thomas Connor Donahue, Sai Pooja Mahajan, May N Taw, Sophia W Hulbert, Erik J Bidstrup, D. Natasha Owitipana, Alexandra Pang, Xu Yang, Souvik Ghosal, Christopher A Alabi, Parastoo Azadi, Jeffrey J. Gray, Michael C Jewett, Lai-Xi Wang, Matthew P DeLisa
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Abstract

Human immunoglobulin G (IgG) antibodies are one of the most important classes of biotherapeutic agents and undergo glycosylation at the conserved N297 site in the CH2 domain, which is critical for IgG Fc effector functions and anti-inflammatory activity. Hence, technologies for producing authentically glycosylated IgGs are in high demand. While attempts to engineer Escherichia coli for this purpose have been described, they have met limited success due in part to the lack of available oligosaccharyltransferase (OST) enzymes that can install N-linked glycans within the QYNST sequon of the IgG CH2 domain. Here, we identified a previously uncharacterized single-subunit OST (ssOST) from the bacterium Desulfovibrio marinus that exhibited greatly relaxed substrate specificity and, as a result, was able to catalyze glycosylation of native CH2 domains in the context of both a hinge-Fc fragment and a full-length IgG. Although the attached glycans were bacterial in origin, conversion to a homogeneous, asialo complex-type G2 N-glycan at the QYNST sequon of the E. coli-derived hinge-Fc was achieved via chemoenzymatic glycan remodeling. Importantly, the resulting G2-hinge-Fc exhibited strong binding to human FcγRIIIa (CD16a), one of the most potent receptors for eliciting antibody-dependent cellular cytotoxicity (ADCC). Taken together, the discovery of DmPglB provides previously unavailable biocatalytic capabilities to the bacterial glycoprotein engineering toolbox and opens the door to using E. coli for the production and glycoengineering of human IgGs and fragments derived thereof.
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发现一种单亚基寡糖基转移酶,它能使大肠杆菌中的全长 IgG 抗体糖基化
人类免疫球蛋白 G(IgG)抗体是最重要的生物治疗剂之一,会在 CH2 结构域的保守 N297 位点发生糖基化,这对 IgG 的 Fc 效应器功能和抗炎活性至关重要。因此,生产真正糖基化 IgG 的技术需求量很大。虽然已经有人尝试为此目的设计大肠杆菌,但取得的成功有限,部分原因是缺乏可在 IgG CH2 结构域的 QYNST 序列内安装 N-连接聚糖的寡糖基转移酶(OST)。在这里,我们从海洋脱硫弧菌(Desulfovibrio marinus)中鉴定出了一种以前未曾定性的单亚基 OST(ssOST),它的底物特异性大大放宽,因此能够在铰链-Fc 片段和全长 IgG 的背景下催化原生 CH2 结构域的糖基化。虽然附着的聚糖来源于细菌,但在大肠杆菌衍生的铰链-Fc 的 QYNST 序列处,通过化学酶促聚糖重塑实现了向均质的、asialo 复合物型 G2 N-聚糖的转化。重要的是,G2-铰链-Fc 与人 FcγRIIIa (CD16a)有很强的结合力,而人 FcγRIIIa (CD16a)是激发抗体依赖性细胞毒性(ADCC)最有效的受体之一。综上所述,DmPglB 的发现为细菌糖蛋白工程工具箱提供了以前无法获得的生物催化能力,并为使用大肠杆菌生产和糖工程化人类 IgG 及其衍生片段打开了大门。
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