Self‐Degradable Lipid‐Like Materials Based on “Hydrolysis accelerated by the intra‐Particle Enrichment of Reactant (HyPER)” for Messenger RNA Delivery

RNA‐based therapeutics is a promising approach for curing intractable diseases by manipulating various cellular functions. For eliciting RNA (i.e., mRNA and siRNA) functions successfully, the RNA in the extracellular space must be protected and it must be delivered to the cytoplasm. In this study, t...

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Published inAdvanced functional materials Vol. 30; no. 34
Main Authors Tanaka, Hiroki, Takahashi, Tatsunari, Konishi, Manami, Takata, Nae, Gomi, Masaki, Shirane, Daiki, Miyama, Ryo, Hagiwara, Shinya, Yamasaki, Yuki, Sakurai, Yu, Ueda, Keisuke, Higashi, Kenjirou, Moribe, Kunikazu, Shinsho, Eiji, Nishida, Ruka, Fukuzawa, Kaori, Yonemochi, Etsuo, Okuwaki, Koji, Mochizuki, Yuji, Nakai, Yuta, Tange, Kota, Yoshioka, Hiroki, Tamagawa, Shinya, Akita, Hidetaka
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.08.2020
Subjects
Aromatic compounds
Cytoplasm
Degradation
Gene expression
Hydrolysis
ionizable lipid
Lipids
Materials science
messenger RNA
nanoemulsion
Nanoparticles
Oleic acid
Ribonucleic acid
RNA
self‐degradability
Thiols
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Summary:RNA‐based therapeutics is a promising approach for curing intractable diseases by manipulating various cellular functions. For eliciting RNA (i.e., mRNA and siRNA) functions successfully, the RNA in the extracellular space must be protected and it must be delivered to the cytoplasm. In this study, the development of a self‐degradable lipid‐like material that functions to accelerate the collapse of lipid nanoparticles (LNPs) and the release of RNA into cytoplasm is reported. The self‐degradability is based on a unique reaction “Hydrolysis accelerated by intra‐Particle Enrichment of Reactant (HyPER).” In this reaction, a disulfide bond and a phenyl ester are essential structural components: concentrated hydrophobic thiols that are produced by the cleavage of the disulfide bonds in the LNPs drive an intraparticle nucleophilic attack to the phenyl ester linker, which results in further degradation. An oleic acid‐scaffold lipid‐like material that mounts all of these units (ssPalmO‐Phe) shows superior transfection efficiency to nondegradable or conventional materials. The insertion of the aromatic ring is unexpectedly revealed to contribute to the enhancement of endosomal escape. Since the intracellular trafficking is a sequential process that includes cellular uptake, endosomal escape, the release of mRNA, and translation, the improvement in each process synergistically enhances the gene expression. Cytoplasmic release of messenger RNA from its drug delivery system is one of the key steps that determines the efficiency of protein production. Intracellular collapse of lipid nanoparticles is facilitated by the self‐degradation of ionizable lipids via a unique intraparticle reaction denoted as “Hydrolysis accelerated by intra‐Particle Enrichment of Reactant (HyPER).”
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201910575