Breaking Endosomal Barriers: Thiol-Mediated Uptake Lipid Nanoparticles for Efficient mRNA Vaccine Delivery

化学 内体 硫醇 纳米颗粒 细胞生物学 纳米技术 生物化学 细胞 生物 材料科学
作者
Zhijie Lian,Lingying Zheng,Shuya Liu,Junjie Zhang,Jie Zhou,Jun Wu,Songying Ouyang,Jingying Li,Huanghao Yang
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:147 (35): 31530-31540 被引量:14
标识
DOI:10.1021/jacs.5c05367
摘要

Lipid nanoparticles (LNPs) are the most clinically advanced delivery platforms for mRNA therapeutics; however, their full potential is significantly limited by suboptimal intracellular mRNA delivery. Herein, we report the rational chemical design and synthesis of a dithiolane-incorporated lipidoid (S-DOPE) to construct an innovative LNP formulation, termed SLNP, for enhanced intracellular mRNA delivery. These chemically engineered SLNPs exploit an inherent thiol-mediated uptake mechanism, whereby the unique dithiolane moiety triggers a dynamic covalent disulfide-thiol exchange reaction with cell surface thiols. This chemically driven reaction facilitates direct cytosolic mRNA delivery, effectively bypassing endosomal entrapment, a major bottleneck for conventional LNPs. In vitro studies demonstrate that SLNP formulations achieve an 11-fold increase in mRNA transfection and translation efficiency compared to standard LNPs. Furthermore, in vivo evaluations reveal a 4.5-fold enhancement in mRNA expression and robust immune responses. SLNP-mediated vaccination at low doses elicits high titers of neutralizing antibodies and a Th1-biased T-cell response. Notably, SLNPs induce neutralizing antibody titers against the SARS-CoV-2 spike protein that are comparable to those achieved with significantly higher doses of conventional LNPs, highlighting their substantial dose-sparing potential. These findings establish that SLNP, by leveraging the chemically innovative thiol-mediated uptake mechanism, offers a promising and chemically distinct strategy to enhance both the efficacy and safety of mRNA vaccines, which is particularly valuable in scenarios of limited vaccine supply and for minimizing potential adverse effects associated with high vaccine dosages.
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