Novel endosomolytic poly(amido amine) polymer conjugates for systemic delivery of siRNA to hepatocytes in rodents and nonhuman primates.

The application of small interfering (si)RNAs as potential therapeutic agents requires safe and effective methods for their delivery to the cytoplasm of the target cells and tissues. Recent studies have shown significant progress in the development of targeting reagents that facilitate the recognition of, and siRNA delivery to, specific cell types. Among recently reported delivery approaches, polymers with amphipathic properties have been used to enable endosome escape and cytosolic delivery. Here, we describe a linear amphipathic poly(amido amine) polymer conjugate system for the efficient siRNA delivery in vitro and in vivo. This polymer contains a novel amine bearing bis-acrylamide monomer designed for increasing amine density, which resulted in substantial improvement in liver uptake and RNAi activity compared to our previously reported poly(amido amine disulfide) polymer.1 The activity for this liver targeted delivery system was demonstrated in rodents and nonhuman primates.

Development of a liver-targeted siRNA delivery platform with a broad therapeutic window utilizing biodegradable polypeptide-based polymer conjugates.

The greatest challenge standing in the way of effective in vivo siRNA delivery is creating a delivery vehicle that mediates a high degree of efficacy with a broad therapeutic window. Key structure-activity relationships of a poly(amide) polymer conjugate siRNA delivery platform were explored to discover the optimized polymer parameters that yield the highest activity of mRNA knockdown in the liver. At the same time, the poly(amide) backbone of the polymers allowed for the metabolism and clearance of the polymer from the body very quickly, which was established using radiolabeled polymers to demonstrate the time course of biodistribution and excretion from the body. The fast degradation and clearance of the polymers provided for very low toxicity at efficacious doses, and the therapeutic window of this poly(amide)-based siRNA delivery platform was shown to be much broader than a comparable polymer platform. The results of this work illustrate that the poly(amide) platform has a promising future in the development of a siRNA-based drug approved for human use.

Synthesis of statistical copolymers containing multiple functional peptides for nucleic Acid delivery.

Our report describes RAFT copolymerization of multiple species of active peptide monomers with N-(2-hydroxypropyl(methacrylamide) (HPMA) under aqueous conditions. Resulting statistical copolymers are narrowly disperse with highly controlled molecular weight and composition. Side-chain peptide copolymers were synthesized using a DNA condensing peptide (K12), and an endosomal escape peptide (K6H5) that had been modified with an aminohexanoic linker and capped with methacrylamide vinyl on the NH2-terminus. Copolymers of HMPA-co-K12 and HPMA-co-K12-co-K6H5 efficiently condensed DNA into small particles that maintain size stability even in 150 mM salt solutions. With increasing peptide content, the peptide-based polymers demonstrated gene delivery efficiencies to HeLa cells that were comparable to branched polyethylenimine.

Synthesis and characterization of biodegradable HPMA-oligolysine copolymers for improved gene delivery.

Bioactive peptides, including DNA-binding, endosomal release, and cell targeting peptides, have been integrated into synthetic gene carriers to improve delivery efficiency by enabling the vectors to overcome barriers to gene delivery. Our overall goal is to develop multifunctional, peptide-based polymers that incorporate motifs to condense DNA and facilitate sequential trafficking steps. One approach is to polymerize vinyl-terminated peptides by radical polymerization. In this work, cationic oligolysine peptides were designed to contain vinyl termini with internal reducible linkers. These peptides were copolymerized with HPMA to form biodegradable, DNA-condensing copolymers for gene delivery. The polymerization conditions were optimized by varying the initiator to monomer ratios, macromonomer to comonomer ratios, and reactant concentrations. The synthesized copolymers were shown to possess several important properties required for in vivo gene delivery applications, including (i) efficient DNA binding and condensation, (ii) the ability to stabilize particles against salt-induced aggregation, (iii) the ability to resist extracellular polyplex unpackaging, (iv) biocompatibility and the potential to be degraded into nontoxic components after cellular uptake, and (v) efficient delivery of plasmid to cultured cells.

Extracellular barriers to in Vivo PEI and PEGylated PEI polyplex-mediated gene delivery to the liver.

Polyplex-mediated gene therapy is a promising alternative to viral gene therapy. One challenge to these synthetic carriers is reduced transfection efficiencies in vivo compared to those achieved in vitro. Many of the intracellular barriers to gene delivery have been elucidated, but similar quantification of extracellular barriers to gene delivery remains a need. In this study, the unpackaging of polyplexes by serum proteins, soluble glycosaminoglycans, and an extracellular matrix extract was demonstrated by a YOYO-1 fluorescence quenching assay. Additionally, exposing polyplexes to serum or proteoglycans before in vitro transfection caused decreased cellular uptake of DNA. Lastly, PEI polyplexes and PEGylated PEI polyplexes were injected into the portal vein of mice, and the intrahepatic distributions of labeled DNA and polymer were assessed by confocal microscopy. PEI polyplexes delivered DNA to the liver, but extensive vector unpackaging was observed, with PEI primarily colocalized with the extracellular matrix. PEGylated polyplexes mediated less DNA delivery to the liver, possibly due to premature vector unpackaging in the blood. Through this work, both the blood and the extracellular matrix have been determined to be significant extracellular barriers to polyplex-mediated in vivo gene delivery to the liver.