核糖核酸
细胞内
内体
凝聚
肽
转染
化学
细胞生物学
核酸
信使核糖核酸
胞浆
生物相容性材料
生物化学
细胞穿透肽
生物物理学
信号肽
生物
HEK 293细胞
翻译(生物学)
德隆
纳米技术
费斯特共振能量转移
合成生物学
舱室(船)
绿色荧光蛋白
小干扰RNA
电穿孔
蛋白质生物合成
肽序列
RNA干扰
内吞作用
基因传递
作者
Shuling Ren,X Lin,Qijing Xie,Siyuan Yu,Xiyu Zheng,Haifeng Pan,S H Tan,Yingbin Wang,Shibo Liu,T. Li,Shengxiang Ge,Jun Zhang,Ningshao Xia
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-12-26
卷期号:20 (1): 459-474
标识
DOI:10.1021/acsnano.5c13501
摘要
Efficient and safe Messenger RNA (mRNA) delivery remains a central challenge in nucleic acid therapeutics. While lipid nanoparticles dominate clinically, their biosafety concerns and poor endosomal escape hinder broader application. Phase-separating peptides (PSPs) offer a biocompatible alternative, but often lack structural stability and precise control over intracellular release. In this study, HBpep-SS4 was developed as a chemically defined coacervate system with intrinsic redox-responsiveness encoded by tandem cysteines in its peptide sequence. This minimalist, single-component design eliminates the need for postsynthetic modifications or protein conjugations, simplifying the synthesis process and reducing potential toxicity. HBpep-SS4 forms stable coacervates capable of encapsulating >95% mRNA and retains responsiveness to glutathione, enabling cytosolic RNA release. It delivers a broad spectrum of RNA cargos─including linear, circular, and self-amplifying RNAs (∼9700 nt)─and achieves high transfection efficiency across multiple cell lines. Functionally, it supports genome editing via SpCas9 mRNA/sgRNA delivery, reaching 86.0% EGFP disruption and 72.5% editing at the HBB locus. Mechanistic studies reveal that HBpep-SS4 enters cells via phagocytosis and bypasses endosomal trafficking, disassembling in reductive environments without toxic byproducts. Building on these findings, HBpep-SS4 was designed with primary sequence-encoded environmental responsiveness, enabling integration of structure, function, and redox sensitivity within a single peptide-based system. Embedding functional reactivity into the peptide backbone supports glutathione-triggered disassembly, which may contribute to improved safety, manufacturing scalability, and potential applicability in RNA-based delivery platforms.
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