Targeted Decationized Polyplexes for Cell Specific Gene Delivery

Novo, Luís; Mastrobattista, Enrico; Nostrum, Cornelus F. van; Hennink, Wim E.

doi:10.1021/bc500074a

Cited by 25 publications

(42 citation statements)

References 50 publications

(98 reference statements)

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“…This result is consistent with the previous report showing a similar decrease of transfection efficiency for PEG-FA conjugated vector in A549 cells. 47 In addition, the fluorescence images ( Figure S6, Supporting Information) confirmed these results. In conclusion, the divalent FA coupling to PME through PEG spacer was more effective in improving transfection activity than the monovalent FA coupling.…”

Section: ■ Results and Discussionsupporting

confidence: 61%

Divalent Folate Modification on PEG: An Effective Strategy for Improving the Cellular Uptake and Targetability of PEGylated Polyamidoamine–Polyethylenimine Copolymer

et al. 2014

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The stability and targeting ability of nanocarrier gene delivery systems are necessary conditions to ensure the good therapeutic effect and low nonspecific toxicity of cancer treatment. Poly(ethylene glycol) (PEG) has been widely applied for improving stability and as a spacer for linking ligands and nanocarriers to improve targetability. However, the cellular uptake and endosomal escape capacity of nanocarriers has been seriously harmed due to the introduction of PEG. In the present study, we synthesized a new gene delivery vector by coupling divalent folate-PEG (PEG3.4k-FA2) onto polyamidoamine-polyethylenimine (PME) copolymer (PME-(PEG3.4k-FA2)1.72). Both PEG and monovalent folate-PEG (PEG3.4k-FA1) modified PME were prepared as control polymers, which were named as PME-(PEG3.5k)1.69 and PME-(PEG3.4k-FA1)1.66, respectively. PME-(PEG3.4k-FA2)1.72 exhibited strong DNA condensation capacity like parent polymer PME which was not significantly influenced by PEG. PME-(PEG3.4k-FA2)1.72/DNA complexes at N/P = 10 had a diameter ∼143 nm and zeta potential ∼13 mV and showed the lowest cytotoxicity and hemolysis and the highest transfection efficiency among all tested polymers. In folate receptor positive (FR-positive) cells, the cellular uptake and transfection efficiency were increased with the increase in the number of folates coupled on PEG; the order was PME-(PEG3.4k-FA2)1.72 > PME-(PEG3.4k-FA1)1.66 > PME-(PEG3.5k)1.69. Folate competition assays showed that PME-(PEG3.4k-FA2)1.72 complexes had stronger targeting ability than PME-(PEG3.5k)1.69 and PME-(PEG3.4k-FA1)1.66 complexes due to their higher folate density per PEG molecule. Cellular uptake mechanism study showed that the folate density on PEG could change the endocytosis pathway of PME-(PEG3.5k)1.69 from clathrin-mediated endocytosis to caveolae-mediated endocytosis, leading to less lysosomal degradation. Distribution and uptake in 3D multicellular spheroid assays showed that divalent folate could offer PME-(PEG3.4k-FA2)1.72 complexes stronger penetrating ability and higher cellular uptake. With these advantages, PME-(PEG3.4k-FA2)1.72 may be a promising nonviral vector candidate for efficient gene delivery. This study also indicates that divalent folate modification on PEG can serve as an efficient strategy to improve the cellular uptake and targeting ability of PEGylated cationic polymers for gene delivery.

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Section: ■ Results and Discussionsupporting

confidence: 61%

Divalent Folate Modification on PEG: An Effective Strategy for Improving the Cellular Uptake and Targetability of PEGylated Polyamidoamine–Polyethylenimine Copolymer

et al. 2014

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“…Additionally, as anticipated, decationized polyplexes have shown an excellent safety profile and extensive in vitro tests have shown that decationized polyplexes do not interfere with cell viability nor induce membrane destabilization at any of the doses tested [19,20]. Furthermore, the neutral block copolymer pHP--PEG that forms decationized polyplexes showed excellent cytocompatibility upon incubation with HUVEC cells.…”

Section: Decationized Polyplexes Propertiesmentioning

confidence: 56%

“…On the other hand, for the cell line (A549) with low folate receptor expression, a similar uptake was observed for both targeted and nontargeted decationized polyplexes. Furthermore, the improved cellular uptake for targeted systems had a direct correlation with improved transfection observed in OVCAR-3 cells [20]. Importantly, the nontargeted cationic system showed the highest cellular uptake, mainly due to nonspecific interaction between the positively charged polyplexes membrane anionic components, which is not favorable for highly specific targeted delivery which requires low uptake by nontarget cells (Figure 2A).…”

Section: Decationized Polyplexes Propertiesmentioning

confidence: 96%

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Decationized polyplexes for gene delivery

Novo¹,

Mastrobattista²,

Nostrum³

et al. 2014

Expert Opinion on Drug Delivery

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“…Regarding the optimization of cell selectivity, multifunctional nanocarriers comprising pDNA-compacting amino acids and targeting moieties have been developed for delivery of genetic material to folate receptor overexpressed in HeLa cervix cancer cells [58]. Recently, to address these issues correlated with the cationic net-charge of polyplexes and stimuli-responsive DNA release in in vivo applications, Novo et al has developed an elegant approach in which polyplexes were initially formed by electrostatic interaction between polymer-pDNA followed by stabilization of the particle through disulfide linkages and finally decationization by removal of the polymer cationic moieties [62]. The final nanocarriers presented negative surface, redox-responsive behavior and selectivity towards folate-receptor-positive cancer cells [62].…”

Section: Therapeutic Applications Of Mcdna Biopharmaceuticalsmentioning

confidence: 99%

Minicircle DNA vectors for gene therapy: advances and applications

Gaspar¹,

Melo‐Diogo²,

Costa³

et al. 2014

Expert Opinion on Biological Therapy

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Achieving in-target and persistent transgene expression is a challenging issue that is of critical importance for a successful therapeutic outcome. The use of miniaturized mcDNA cassettes with additional modifications that increase and prolong expression may contribute to an improved generation of biopharmaceuticals. The unique features of mcDNA render it an attractive alternative to overcome current technical issues and to bridge the significant gap that exists between basic research and clinical applications.

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Targeted Decationized Polyplexes for Cell Specific Gene Delivery

Cited by 25 publications

References 50 publications

Divalent Folate Modification on PEG: An Effective Strategy for Improving the Cellular Uptake and Targetability of PEGylated Polyamidoamine–Polyethylenimine Copolymer

Divalent Folate Modification on PEG: An Effective Strategy for Improving the Cellular Uptake and Targetability of PEGylated Polyamidoamine–Polyethylenimine Copolymer

Decationized polyplexes for gene delivery

Minicircle DNA vectors for gene therapy: advances and applications

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