EGF receptor targeted lipo-oligocation polyplexes for antitumoral siRNA and miRNA delivery.

Antitumoral siRNA and miRNA delivery was demonstrated by epidermal growth factor receptor (EGFR) targeted oligoaminoamide polyplexes. For this purpose, the T-shaped lipo-oligomer 454 was used to complex RNA into a core polyplex, which was subsequently functionalized with the targeting peptide ligand GE11 via a polyethylene glycol (PEG) linker. To this end, free cysteines on the surface of 454 polyplex were coupled with a maleimide-PEG-GE11 reagent (Mal-GE11). Resulting particles with sizes of 120-150 nm showed receptor-mediated uptake into EGFR-positive T24 bladder cancer cells, MDA-MB 231 breast cancer cells and Huh7 liver cancer cells. Furthermore, these formulations led to ligand-dependent gene silencing. RNA interference (RNAi) triggered antitumoral effects were observed for two different therapeutic RNAs, a miRNA-200c mimic or EG5 siRNA. Using polyplexes modified with a ratio of 0.8 molar equivalents of Mal-GE11, treatment of T24 or MDA-MB 231 cancer cells with miR-200c led to the expected decreased proliferation and migration, changes in cell cycle and enhanced sensitivity towards doxorubicin. Delivery of EG5 siRNA into Huh7 cells resulted in antitumoral activity with G2/M arrest, triggered by loss of mitotic spindle separation and formation of mono-astral spindles. These findings demonstrate the potential of GE11 ligand-containing RNAi polyplexes for cancer treatment.

Post-PEGylation of siRNA Lipo-oligoamino Amide Polyplexes Using Tetra-glutamylated Folic Acid as Ligand for Receptor-Targeted Delivery.

For efficient and receptor-specific siRNA delivery, a new post-PEGylation strategy was established to provide siRNA polyplexes with targeting and shielding agents. For this purpose, core nanoparticles were formed by complexing siRNA with sequence-defined cationic lipo-oligomers. The T-shaped bis-oleoyl-oligoethanamino amides 454 and 595, containing stabilizing tyrosine and cysteine residues, were applied. These core nanoparticles were surface-shielded by reaction with maleimido-polyethylene glycol (Mal-PEG) reagents, optionally containing the targeting ligand folic acid (FolA). The PEGylation had two unpredicted consequences. First, FolA-PEG surface-modified polyplexes agglomerated due to the hydrophobicity of folic acid, resulting in ligand-independent gene silencing. This problem was solved by the use of tetra-γ-glutamyl folic acid (gE4-FolA) as targeting ligand. Post-PEGylated gE4-FolA siRNA polyplexes displayed sizes of 100-200 nm and mediated receptor specific uptake and effective gene silencing. Second, PEGylation triggered a destabilization of polyplexes, which was uncritical in cell culture but a limiting factor in vivo, as revealed by biodistribution studies in mice. This problem was partially overcome by selecting 595 (containing two CRC stability motifs) for polyplex core formation and an optimized lower degree of gE4-FolA PEGylation reagent. Biodistribution in L1210 tumor bearing mice demonstrated a significantly reduced lung signal and extended persistence of siRNA polyplexes (up to 8 h), with moderate delivery into the tumor. Further polyplex stabilization will be required for effective tumor-targeted delivery.

Targeted siRNA Delivery Using a Lipo-Oligoaminoamide Nanocore with an Influenza Peptide and Transferrin Shell.

Developing RNA-interference-based therapeutic approaches with efficient and targeted cytosolic delivery of small interfering RNA (siRNA) is remaining a critical challenge since two decades. Herein, a multifunctional transferrin receptor (TfR)-targeted siRNA delivery system (Tf&INF7) is designed based on siRNA complexes formed with the cationic lipo-oligoamino amide 454, sequentially surface-modified with polyethylene glycol-linked transferrin (Tf) for receptor targeting and the endosomolytic peptide INF7 for efficient cytosolic release of the siRNA. Effective Tf&INF7 polyplex internalization and target gene silencing are demonstrated for the TfR overexpressing tumor cell lines (K562, D145, and N2a). Treatment with antitumoral EG5 siRNA results in a block of tumor cell growth and triggered apoptosis. Tf-modified polyplexes are far more effective than the corresponding albumin- (Alb) or nonmodified 454 polyplexes. Competition experiments with excess of Tf demonstrate TfR target specificity. As alternative to the ligand Tf, an anti-murine TfR antibody is incorporated into the polyplexes for specific targeting and gene silencing in the murine N2a cell line. In vivo distribution studies not only demonstrate an enhanced tumor residence of siRNA in N2a tumor-bearing mice with the Tf&INF7 as compared to the 454 polyplex group but also a reduced siRNA nanoparticle stability limiting the in vivo performance.

DNA as Tunable Adaptor for siRNA Polyplex Stabilization and Functionalization.

siRNA and microRNA are promising therapeutic agents, which are engaged in a natural mechanism called RNA interference that modulates gene expression posttranscriptionally. For intracellular delivery of such nucleic acid triggers, we use sequence-defined cationic polymers manufactured through solid phase chemistry. They consist of an oligoethanamino amide core for siRNA complexation and optional domains for nanoparticle shielding and cell targeting. Due to the small size of siRNA, electrostatic complexes with polycations are less stable, and consequently intracellular delivery is less efficient. Here we use DNA oligomers as adaptors to increase size and charge of cargo siRNA, resulting in increased polyplex stability, which in turn boosts transfection efficiency. Extending a single siRNA with a 181-nucleotide DNA adaptor is sufficient to provide maximum gene silencing aided by cationic polymers. Interestingly, this simple strategy was far more effective than merging defined numbers (4-10) of siRNA units into one DNA scaffolded construct. For DNA attachment, the 3' end of the siRNA passenger strand was beneficial over the 5' end. The impact of the attachment site however was resolved by introducing bioreducible disulfides at the connection point. We also show that DNA adaptors provide the opportunity to readily link additional functional domains to siRNA. Exemplified by the covalent conjugation of the endosomolytic influenza peptide INF-7 to siRNA via a DNA backbone strand and complexing this construct with a targeting polymer, we could form a highly functional polyethylene glycol-shielded polyplex to downregulate a luciferase gene in folate receptor-positive cells.

Dual antitumoral potency of EG5 siRNA nanoplexes armed with cytotoxic bifunctional glutamyl-methotrexate targeting ligand.

Synthetic small interfering RNA (siRNA) is a class of therapeutic entities that allow for specific silencing of target genes via RNA interference (RNAi) and comprise an enormous clinical potential for a variety of diseases, including cancer. However, efficient tissue-specific delivery of siRNA remains the major limitation in the development of RNAi-based cancer therapeutics. To achieve this, we have synthesized a series of sequence-defined oligomers, which include a cationic (oligoethanamino)amide core (for nanoparticle formation with siRNA), cysteines (as bioreversible disulfide units), and a polyethylene glycol chain (for shielding of surface charges) coupled to a terminal targeting ligand. The antifolate drug methotrexate (MTX), a well-established chemotherapeutic agent, serves as both targeting ligand and anticancer agent. The oligomers form homogeneous spherical siRNA polyplexes with a hydrodynamic diameter of approximately 6 nm. These polyplexes access KB cells by binding to the folate receptor in a MTX-dependent manner and induce efficient gene silencing activity in vitro. Impressively, in the in vivo studies, MTX-conjugated polyplexes significantly increase the intratumoral retention (168 h) of the siRNA, as compared to alanine-substituted non-targeted control polyplexes (48 h). The combination of MTX-conjugated polyplexes and eglin 5 (EG5) siRNA provides enhanced antitumoral potency with 50% of recurrence-free survival of KB tumor-bearing mice. The design of such siRNA carrier systems with a dual-functional ligand for cellular delivery and augmented tumor suppression could be a valuable strategy for translating RNAi-based cancer therapeutics to the clinics.

Twin disulfides as opportunity for improving stability and transfection efficiency of oligoaminoethane polyplexes.

The synthesis of precise gene delivery vehicles by solid-supported chemistry is an effective way to establish structure-activity relationships and optimize existing transfection carriers. Sequence-defined cationic oligomers with different topologies were modified with twin disulfide-forming cysteine-arginine-cysteine (CRC) motifs. The influence of this motif versus single disulfide on the biophysical properties and biological performance of polyplexes was investigated, with pDNA and siRNA as nucleic acid cargoes. Clear differences between structures with isolated cysteines and CRC motifs were observed with respect to properties like nucleic acid binding, serum stability, response to reducing agents, and gene transfer/silencing. The main observed effect of the CRC motif was to increase polyplex stability. The consequences for nucleic acid delivery were less predictable and depended on oligomer topology. For some oligomers intrinsically forming stable polyplexes (i.e., already in the absence of CRC motif), this further stabilization resulted in a reduction or even loss in transfection efficiency. For PEGylated and targeted oligomers with intrinsically less stable polyplex structures, this modification led to a significant enhancement in transfection efficiency.

Bioreducible polycations as shuttles for therapeutic nucleic acid and protein transfection.

SIGNIFICANCE: Nucleic acids such as gene-encoding DNAs, gene-silencing small interfering RNAs, or recombinant proteins addressing intracellular molecular targets present a major new therapeutic modality, provided efficient solutions for intracellular delivery can be found. The different physiological redox environments inside and outside the cell can be utilized for optimizing the involved transport processes. RECENT ADVANCES: Intracellular delivery of nucleic acids or proteins requires dynamic carriers that discriminate between different cellular locations. Bioreducible cationic polymers can package their therapeutic cargo stably in the extracellular environment, but sense the reducing intracellular cytosolic environment. Based on disulfide cleavage, carriers are degraded into biocompatible fragments and release the cargo in functional form. Disulfide linkages between oligocations, between the carrier and the cargo, or spatial caging of complexed cargo by disulfides have been pursued, with polymers or precise sequence-defined peptides and oligomers. CRITICAL ISSUES: A quantitative knowledge of the bioreductive capacities within different biological compartments and the involved cellular reduction processes would be greatly helpful for improved carriers with disulfides cleaved within the right compartment at the right time. FUTURE DIRECTIONS: Novel designs of multifunctional nanocarriers will incorporate macromolecular disulfide entry mechanisms previously optimized by natural evolution of toxins and viruses. In addition to extracellular stabilization and intracellular disassembly, tuned disulfides will contribute to deshielding at the cell surface, or translocation from intracellular compartments to the cytosol.