化学
合理设计
体内
分子动力学
转染
信使核糖核酸
纳米颗粒
基因传递
生物物理学
分子间力
酶
分子模型
生物化学
体外
组合化学
分子探针
药物输送
输送系统
分子
脂泡
立体化学
分子力学
分子工程
纳米技术
计算生物学
细胞培养
作者
Zepeng He,Zhijia Liu,Taisen Zuo,Zhan Gao,Haihong Yang,Ziying Zhang,Yongzhen Chu,Zheqi Li,Xueer Ge,Xiaorong Pan,Gege Zeng,Hong Zhu,Jialu Li,Hong Liu,Yi Shi,Lixin Liu,He Cheng,Yongming Chen
摘要
Lipid nanoparticles (LNPs) have been demonstrated as effective mRNA delivery systems, with ionizable lipids (ILs) serving as critical determinants of their in vivo delivery efficacy. However, elucidating the structure–activity relationship of ILs remains a formidable challenge, hindering the rational design of next-generation LNPs with improved efficiency and targeting specificity. Here, we present a straightforward and powerful isomerism strategy for the efficient synthesis of 9 isomeric ILs using a four-component Ugi reaction (Ugi-4CR). Molecular dynamics simulations and small-angle neutron scattering investigations revealed that differences in IL isomerism lead to distinct IL-mRNA intermolecular interactions and varied IL distribution patterns within LNPs, ultimately resulting in variations in the apparent p K a of LNPs. In vivo evaluation demonstrated that isomeric ILs contribute to different transfection profiles across liver cell types following intravenous administration, enhance muscle-selective mRNA delivery after intramuscular administration, and modulate the delivery efficiency of DOTAP-mediated lung-targeted LNPs. The establishment of IL isomerism not only introduces a new molecular design dimension for IL optimization but also lays the foundation for the rational design of ILs for targeted mRNA delivery, thus expanding the potential applications of mRNA therapeutics.
科研通智能强力驱动
Strongly Powered by AbleSci AI