刺
干扰素基因刺激剂
生物
计算生物学
免疫系统
干扰素
机制(生物学)
先天免疫系统
信号
基因
细胞生物学
免疫
细胞因子
遗传学
表型
进化生物学
信号通路
自噬
获得性免疫系统
信号转导
生物信息学
功能多样性
细胞内
基因表达调控
分子进化
作者
Bing Zhang,Pengbiao Xu,Yu Meng,Laure Gallay,F Lestelle,Hélène Morel,Marie-Louise Frémond,Bruno E. Correia,Andrea Ablasser
出处
期刊:Nature
[Nature Portfolio]
日期:2026-06-24
标识
DOI:10.1038/s41586-026-10685-3
摘要
Stimulator of interferon genes (STING) is an evolutionary conserved immune signalling protein with key roles in host defence, cancer, senescence and inflammation1–3. Downstream of STING, type I interferon, inflammatory cytokine signalling and non-canonical autophagy are governed by a multilayered mechanism integrating ligand-induced structural transitions, protein–protein interactions and coordinated intracellular trafficking4–13. Despite its central role in immunity and relevance as therapeutic target14, the sequence elements that govern STING (in)activation in cells remain incompletely understood. Here we developed a massively parallel assay to systematically chart the sequence-function landscape of STING. Profiling thousands of single amino-acid variants, we identified structural and functional determinants that shape the immunostimulatory capacity of STING and its ability to translate ligand recognition into distinct signalling outputs. Cryogenic-electron microscopy structures of select STING hyperactive variants revealed new regulatory principles dictating conformational transition from inactive to signalling-competent states of STING. Mutational effects are widespread across the functional landscape and can sensitize STING towards the natural ligand 2′3′-cGAMP15–18 or decouple interferon induction from non-canonical autophagy, demonstrating a diversity of possible responses that can be accessed through single point substitutions. Finally, our data showed the clinical and evolutionary relevance of naturally occurring STING protein variants. Collectively, these findings define molecular principles that tune STING activity and chart the landscape of its functional potential across immune contexts. A massively parallel assay systematically charts the sequence-function landscape of the STING signalling protein, and the findings define molecular principles that tune STING activity and show its functional potential across immune contexts.
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