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Rational design of engineered H-ferritin nanoparticles with improved siRNA delivery efficacy across an <i>in vitro</i> model of the mouse BBB

Ziwei Yuan, Bin Wang, Yilong Teng, William Ho, Bin Hu, Kofi Oti Boakye‐Yiadom, Xiaoyang Xu, Xue‐Qing Zhang

2022Nanoscale37 citationsDOI

Abstract

interactions with the transferrin receptor 1 (TfR1) overexpressed on their surfaces, which increases uptake through the BBB. However, the gene-loading capacity of HFn is restricted by its limited interior volume and negatively charged inner surface; therefore, these drawbacks have prompted the demand for strategies to remould the structure of HFn. In this work, we analyzed the three-dimensional (3D) structure of HFn using Chimera software (v 1.14) and developed a class of internally cationic HFn variants (HFn+ NPs) through arginine mutation on the lumenal surface of HFn. These HFn+ NPs presented powerful electrostatic forces in their cavities, and exhibited higher gene encapsulation efficacy than naive HFn. The top-performing candidate, HFn2, effectively delivered siRNA to glioma cells after traversing the BBB and achieved the highest silencing efficacy among HFn+ NPs. Overall, our findings demonstrate that HFn+ NPs obtained by this genetic engineering method provide critical insights into the future development of nucleic acid delivery carriers with BBB-crossing ability.

Topics & Concepts

TranscytosisBlood–brain barrierTransferrin receptorLiposomeGliomaGene deliveryBiophysicsChemistryFerritinDrug delivery to the brainGenetic enhancementCancer researchMaterials scienceNanotechnologyTransferrinMedicineGeneBiologyCellEndocytosisBiochemistryNeuroscienceCentral nervous systemRNA Interference and Gene DeliveryIron Metabolism and DisordersExtracellular vesicles in disease
Rational design of engineered H-ferritin nanoparticles with improved siRNA delivery efficacy across an <i>in vitro</i> model of the mouse BBB | Litcius