Three-layered polyplex micelle as a multifunctional nanocarrier platform for light-induced systemic gene transfer

Nanocarriers responding to light have great potential for pinpoint therapy, and recent studies have revealed promising in vivo activity. However, light-selective gene transfer still remains challenging in the systemic application. Here we report systemic light-responsive nanocarriers for gene delive...

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Veröffentlicht in:Nature communications 2014-04, Vol.5 (1), p.3545-3545, Article 3545
Hauptverfasser: Nomoto, Takahiro, Fukushima, Shigeto, Kumagai, Michiaki, Machitani, Kaori, Arnida, Matsumoto, Yu, Oba, Makoto, Miyata, Kanjiro, Osada, Kensuke, Nishiyama, Nobuhiro, Kataoka, Kazunori
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Sprache:eng
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Zusammenfassung:Nanocarriers responding to light have great potential for pinpoint therapy, and recent studies have revealed promising in vivo activity. However, light-selective gene transfer still remains challenging in the systemic application. Here we report systemic light-responsive nanocarriers for gene delivery developed through the sequential self-assembly of ABC-type triblock copolymer/DNA/dendrimeric photosensitizer, forming polyplex micelles with three-layered functional nanocompartments. The DNA-packaged core is covered by the photosensitizer-incorporated intermediate layer, which is encompassed by an outer shielding shell. This three-layered structure permits multistep photosensitizer and DNA delivery into a solid tumour by a systemic route: the shielding layer minimizes unfavourable interactions with blood components, and the photosensitizer is delivered to endo-/lysosomal membranes to facilitate light-selective cytoplasmic translocation of the micelles, accomplishing DNA delivery into the nucleus to exert gene expression. The polyplex micelles display >100-fold photoenhanced gene expression in cultured cells and exhibit light-induced in vivo gene transfer in solid tumours following systemic administration. Light-controlled mechanisms for the delivery of drug molecules to cells is a promising route for non-invasive disease therapy. Here, the authors develop a photosensitive polymeric micelle for light-induced gene transfection and show its effectiveness in vivo via systemic administration.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms4545