Muri Han scite author profile

As a naturally occurring nanocapsule abundantly expressed in nearly all-eukaryotic cells, the barrel-shaped vault particle is perhaps an ideal structure to engineer for targeting to specific cell types. Recombinant vault particles self-assemble from 96 copies of the major vault protein (MVP), have dimensions of 72.5 × 41 nm, and have a hollow interior large enough to encapsulate hundreds of proteins. In this study, three different tags were engineered onto the C-terminus of MVP: an 11 amino acid epitope tag, a 33 amino acid IgG-binding peptide, and the 55 amino acid epidermal growth factor (EGF). These modified vaults were produced using a baculovirus expression system. Our studies demonstrate that recombinant vaults assembled from MVPs containing C-terminal peptide extensions, display these tags at the top and bottom of the vault on the outside of the particle, and can be used to specifically bind the modified vaults to epithelial cancer cells (A431) via the epidermal growth factor receptor (EGFR), either directly (EGF modified vaults) or as mediated by a monoclonal antibody (anti-EGFR) bound to recombinant vaults containing the IgG-binding peptide. The ability to target vaults to specific cells represents an essential advance towards using recombinant vaults as delivery vehicles.

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Charge‐Conversion Ternary Polyplex with Endosome Disruption Moiety: A Technique for Efficient and Safe Gene Delivery

Lee

et al. 2008

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Transfection study using multicellular tumor spheroids for screening non-viral polymeric gene vectors with low cytotoxicity and high transfection efficiencies

Han

Bae

Nishiyama

et al. 2007

Journal of Controlled Release

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Charge‐Conversion Ternary Polyplex with Endosome Disruption Moiety: A Technique for Efficient and Safe Gene Delivery

Miyata

Oba

et al. 2008

Angewandte Chemie

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Targeted Vault Nanoparticles Engineered with an Endosomolytic Peptide Deliver Biomolecules to the Cytoplasm

et al. 2011

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Vault nanoparticles were engineered to enhance their escape from the endosomal compartment by fusing a membrane lytic peptide derived from adenovirus protein VI (pVI) to the N-terminus of the major vault protein to form pVI-vaults. We demonstrate that these pVI-vaults disrupt the endosomal membrane using three different experimental protocols including: 1) enhancement of DNA transfection, 2) co-delivery of a cytosolic ribotoxin, and 3) direct visualization by fluorescence. Furthermore, direct targeting of vaults to specific cell surface epidermal growth factor receptors led to enhanced cellular uptake and efficient delivery of vaults to the cytoplasm. This process was monitored with fluorescent vaults and morphological changes in the endosomal compartment were observed. By combining targeting and endosomal escape into a single recombinant vault, high levels of transfection efficiency were achieved using low numbers of vault particles. These results demonstrate that engineered vaults are effective, efficient, and non-toxic nanoparticles for targeted delivery of biomaterials to the cell cytoplasm.

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Muri Han

Targeting Vault Nanoparticles to Specific Cell Surface Receptors

Charge‐Conversion Ternary Polyplex with Endosome Disruption Moiety: A Technique for Efficient and Safe Gene Delivery

Transfection study using multicellular tumor spheroids for screening non-viral polymeric gene vectors with low cytotoxicity and high transfection efficiencies

Charge‐Conversion Ternary Polyplex with Endosome Disruption Moiety: A Technique for Efficient and Safe Gene Delivery

Targeted Vault Nanoparticles Engineered with an Endosomolytic Peptide Deliver Biomolecules to the Cytoplasm

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