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Abstract

The development of delivery vehicles for small interfering RNAs (siRNAs) remains a bottleneck to widespread clinical use. Cationic polymers represent an important class of potential delivery vehicles. In this study, we used alkyne-azide click chemistry to synthesize a variety of cationic poly(propargyl glycolide) backbone polymers to bind and deliver siRNAs. We demonstrated control over the binding interactions of these polymers and siRNAs by varying binding strength by more than three orders of magnitude. Binding strength was found to meet or exceed that of commercially available transfection agents. Our polymers effectively delivered siRNAs with no detectable cytotoxicity. Despite accumulation of siRNAs at levels comparable with commercial reagents, we did not observe silencing of the targeted protein. The implications of our results for future siRNA delivery vehicle design are discussed.

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References

Oliveira

, Storm

and Schiffelers

. (2006). Targeted delivery of siRNA. J Biomed Biotechnol, 2006:1–9.

Angart

, Vocelle

, Chan

and Walton

. (2013). Design of siRNA therapeutics from the molecular scale. Pharmaceuticals, 6:440–468.

Setten

, Rossi

and Han

. (2019). The current state and future directions of RNAi-based therapeutics. Nat Rev Drug Discov, 18:421–446.

Kanasty

, Dorkin

, Vegas

and Anderson

. (2013). Delivery materials for siRNA therapeutics. Nat Mater, 12:967–977.

O'Mahony

, Ogier

, Desgranges

, Cryan

, Darcy

and O'Driscoll

. (2012). A click chemistry route to 2-functionalised PEGylated and cationic β-cyclodextrins: co-formulation opportunities for siRNA delivery. Org Biomol Chem, 10:4954–4960.

Jiang

, Vogel

, Smith

and Baker

. (2008). “Clickable” polyglycolides: tunable synthons for, thermoresponsive, degradable polymers. Macromolecules 41:1937–1944.

Howard

, Rahbek

, Liu

, Damgaard

, Glud

, Andersen

, Hovgaard

, Schmitz

, Nyengaard

, Besenbacher

and Kjems

. (2006). RNA interference in vitro and in vivo using a novel chitosan/siRNA nanoparticle system. Mol Ther, 14:476–484.

Nelson

, Kintzing

, Hanna

, Shannon

, Gupta

and Duvall

. (2013). Balancing cationic and hydrophobic content of PEGylated siRNA polyplexes enhances endosome escape, stability, blood circulation time, and bioactivity in vivo. ACS Nano, 7:8870–8880.

Patil

and Panyam

. (2009). Polymeric nanoparticles for siRNA delivery and gene silencing. Int J Pharm, 367:195–203.

10.

Tsai

, Chen

, Te Chien

, Chen

, Lin

KMC

, Hwu

, Yang

and Lin

. (2011). A single-monomer derived linear-like PEI-co-PEG for siRNA delivery and silencing. Biomaterials, 32:3647–3653.

11.

Zhu

, Jung

, Luo

, Meng

, Zhu

, Park

and Zhong

. (2010). Co-delivery of siRNA and paclitaxel into cancer cells by biodegradable cationic micelles based on PDMAEMA-PCL-PDMAEMA triblock copolymers. Biomaterials, 31:2408–2416.

12.

Kolb

, Finn

and Sharpless

. (2001). Click chemistry: diverse chemical function from a few good reactions. Angew Chem Int Ed, 40:2004–2021.

13.

Günay

, Theato

and Klok

. (2013). Standing on the shoulders of hermann staudinger: post-polymerization modification from past to present. J Polym Sci Part A Polym Chem, 51:1–28.

14.

Rostovtsev

, Green

, Fokin

and Sharpless

. (2002). A stepwise huisgen cycloaddition process: copper(I)-catalyzed regioselective “ligation” of azides and terminal alkynes. Angew Chem Int Ed, 41:2596–2599.

15.

Haldón

, Nicasio

and Pérez

. (2015). Copper-catalysed azide-alkyne cycloadditions (CuAAC): an update. Org Biomol Chem, 13:9528–9550.

16.

Portis

, Carballo

, Baker

, Chan

and Walton

. (2010). Confocal microscopy for the analysis of siRNA delivery by polymeric nanoparticles. Microsc Res Tech, 73:878–885.

17.

Hill

. (1910). The possible effects of the aggregation of molecules of haemoglobin on its dissociation curves. J Physiol, 40:iv–vii.

18.

Liu

, Howard

, Dong

, Andersen

, Rahbek

, Johnsen

, Hansen

, Besenbacher

and Kjems

. (2007). The influence of polymeric properties on chitosan/siRNA nanoparticle formulation and gene silencing. Biomaterials, 28:1280–1288.

19.

Kakizawa

and Kataoka

. (2002). Block copolymer micelles for delivery of gene and related compounds. Adv Drug Deliv Rev, 54:203–222.

20.

Kim

, Miyata

, Nomoto

, Zheng

, Kim

, Liu

, Cabral

, Christie

, Nishiyama

and Kataoka

. (2014). SiRNA delivery from triblock copolymer micelles with spatially-ordered compartments of PEG shell, siRNA-loaded intermediate layer, and hydrophobic core. Biomaterials, 35:4548–4556.

21.

Zhu

, Tang

, Law

, Feng

, Ho

, Lee

DKL

, Harris

and Li

. (2005). Amphiphilic core-shell nanoparticles with poly(ethylenimine) shells as potential gene delivery carriers. Bioconjug Chem, 16:139–146.

22.

Boussif

, LezoualC'H

, Zanta

, Mergny

, Scherman

, Demeneix

and Behr

. (1995). A versatile vector for gene and oligonucleotide transfer into cells in culture and in vivo: polyethylenimine. Proc Natl Acad Sci U S A, 92:7297–7301.

23.

Benjaminsen

, Mattebjerg

, Henriksen

, Moghimi

and Andresen

. (2013). The possible “proton sponge” effect of polyethylenimine (PEI) does not include change in lysosomal pH. Mol Ther, 21:149–157.

24.

Kandil

, Xie

, Heermann

, Isert

, Jung

, Mehta

and Merkel

. (2019). Coming in and finding out: blending receptor-targeted delivery and efficient endosomal escape in a novel bio-responsive siRNA delivery system for gene knockdown in pulmonary T cells. Adv Ther, 2:1900047–1900061.

25.

Sahay

, Querbes

, Alabi

, Eltoukhy

, Sarkar

, Zurenko

, Karagiannis

, Love

, Chen

, et al. (2013). Efficiency of siRNA delivery by lipid nanoparticles is limited by endocytic recycling. Nat Biotechnol, 31:653–658.

26.

Vocelle

, Chan

and Walton

. (2020). Endocytosis controls small interfering RNA efficiency: implications for small interfering RNA delivery vehicle design and cell-specific targeting. Nucleic Acid Ther, 30:22–32.

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Modulating Polymer-siRNA Binding Does Not Promote Polyplex-Mediated Silencing

Abstract

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