核酸
生物
自催化
计算生物学
原位
合成生物学
生物系统
基质(水族馆)
酶
生物物理学
DNA
计算机科学
聚合酶
纳米技术
指数增长
灵敏度(控制系统)
蛋白质工程
组合化学
寡核苷酸
蛋白质设计
定向分子进化
底物特异性
信使核糖核酸
材料科学
生物化学
分子探针
核酸热力学
作者
Tiantian Yang,Man Tang,Li Xu,Lanxin Jiang,Ling Jiang,Yuting Zou,Jing Wang,Zhangling Liu,Fengjiao Chen,Yanna Ban,Wenlong Ren,Wei Cheng
摘要
The CRISPR/Cas system is a powerful tool for molecular diagnostics, but its reliance on linear amplification constrains sensitivity, particularly for in situ imaging. Here, we discovered that phosphorothioate (PS)-modified activators can modulate Cas enzyme conformation via hydrophobic anchoring. By adjusting the PS modification sites, we achieved precise control over Cas activation and trans-cleavage resistance. Guided by this mechanism, we proposed a tailored design strategy featuring a "scattered" PS modification to engineer a linear "Coordinator" probe. This design effectively decouples Cas enzyme activation from substrate trans-cleavage resistance, enabling the construction of a Scattered PS Nucleic Acid-driven Cas Autocatalytic system (SACA). SACA achieves exponential amplification without external enzymes, enhancing Cas12a and Cas13a sensitivity by 50 000-fold and 10 000-fold, respectively. Furthermore, the superior biostability and structural simplicity of these linear probes endow SACA with excellent compatibility, facilitating precise in situ imaging of HPV16 and HPV18 mRNA in cervical cancer cells. This study not only advances the understanding of Cas enzyme regulation by chemically modified nucleic acids but also establishes a new paradigm for precise and efficient molecular diagnostics.
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