Department of Biochemistry and Molecular Biology, University of Georgia, Athens, United States.
Complex Carbohydrate Research Center, University of Georgia, Athens, United States.
Elife. 2024 Oct 25;13:RP100083. doi: 10.7554/eLife.100083.
Both endogenous antibodies and a subset of antibody therapeutics engage Fc gamma receptor (FcγR)IIIa/CD16a to stimulate a protective immune response. Increasing the FcγRIIIa/IgG1 interaction improves the immune response and thus represents a strategy to improve therapeutic efficacy. FcγRIIIa is a heavily glycosylated receptor and glycan composition affects antibody-binding affinity. Though our laboratory previously demonstrated that natural killer (NK) cell N-glycan composition affected the potency of one key protective mechanism, antibody-dependent cell-mediated cytotoxicity (ADCC), it was unclear if this effect was due to FcγRIIIa glycosylation. Furthermore, the structural mechanism linking glycan composition to affinity and cellular activation remained undescribed. To define the role of individual amino acid and N-glycan residues, we measured affinity using multiple FcγRIIIa glycoforms. We observed stepwise affinity increases with each glycan truncation step, with the most severely truncated glycoform displaying the highest affinity. Removing the N162 glycan demonstrated its predominant role in regulating antibody-binding affinity, in contrast to four other FcγRIIIa N-glycans. We next evaluated the impact of the N162 glycan on NK cell ADCC. NK cells expressing the FcγRIIIa V158 allotype exhibited increased ADCC following kifunensine treatment to limit N-glycan processing. Notably, an increase was not observed with cells expressing the FcγRIIIa V158 S164A variant that lacks N162 glycosylation, indicating that the N162 glycan is required for increased NK cell ADCC. To gain structural insight into the mechanisms of N162 regulation, we applied a novel protein isotope labeling approach in combination with solution NMR spectroscopy. FG loop residues proximal to the N162 glycosylation site showed large chemical shift perturbations following glycan truncation. These data support a model for the regulation of FcγRIIIa affinity and NK cell ADCC whereby composition of the N162 glycan stabilizes the FG loop and thus the antibody-binding site.
内源性抗体和一部分抗体治疗药物与 Fcγ 受体 (FcγR)IIIa/CD16a 结合,以刺激保护性免疫反应。增加 FcγRIIIa/IgG1 的相互作用可以改善免疫反应,因此是提高治疗效果的一种策略。FcγRIIIa 是一种高度糖基化的受体,糖基组成会影响抗体的结合亲和力。虽然我们实验室之前已经证明自然杀伤 (NK) 细胞的 N-聚糖组成会影响一种关键的保护性机制,即抗体依赖性细胞介导的细胞毒性 (ADCC) 的效力,但尚不清楚这种影响是否归因于 FcγRIIIa 的糖基化。此外,将聚糖组成与亲和力和细胞激活联系起来的结构机制仍未被描述。为了确定单个氨基酸和 N-聚糖残基的作用,我们使用多种 FcγRIIIa 糖型来测量亲和力。我们观察到,随着聚糖截断步骤的增加,亲和力呈逐步增加,截断最严重的糖型显示出最高的亲和力。去除 N162 聚糖表明其在调节抗体结合亲和力方面起着主要作用,而其他四个 FcγRIIIa N-聚糖则不是。接下来,我们评估了 N162 聚糖对 NK 细胞 ADCC 的影响。用 kifunensine 处理以限制 N-聚糖加工后,表达 FcγRIIIa V158 同种型的 NK 细胞表现出增强的 ADCC。值得注意的是,在表达缺乏 N162 糖基化的 FcγRIIIa V158 S164A 变体的细胞中没有观察到增加,表明 N162 聚糖是增强 NK 细胞 ADCC 所必需的。为了深入了解 N162 调节的机制,我们应用了一种新的蛋白质同位素标记方法与溶液 NMR 光谱学相结合。接近 N162 糖基化位点的 FG 环残基在聚糖截断后表现出较大的化学位移扰动。这些数据支持了 FcγRIIIa 亲和力和 NK 细胞 ADCC 调节的模型,其中 N162 聚糖的组成稳定了 FG 环,从而稳定了抗体结合位点。
