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.

Gene silencing and antitumoral effects of Eg5 or Ran siRNA oligoaminoamide polyplexes.

Two antitumoral siRNAs (directed against target genes Eg5 and Ran) complexed with one of three sequence-defined cationic oligomers were compared in gene silencing in vitro and antitumoral in vivo efficacy upon intratumoral injection. Two lipo-oligomers (T-shape 49, i-shape 229) and the three-arm oligomer 386 were chosen because of their high efficiency in previous marker gene silencing screens. The oligomers showed very similar target-specific gene knockdown in murine neuroblastoma cells.

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.

Characterization and compatibility of hydroxyethyl starch-polyethylenimine copolymers for DNA delivery.

Hydroxyethyl starch (HES) has been proposed as a biodegradable polymer for shielding of DNA polyplexes, where the feasibility of this approach was shown both in vitro and in vivo. In this study, we report on the physicochemical characterization, the in vitro cytocompatibility and hemotoxicity of HES-decorated polyplexes. For this purpose, various HES molecules were coupled to a 22 kDa linear polyethylenimine (LPEI22) to produce a library of nine different HES-PEI conjugates.

Synthetic polyglutamylation of dual-functional MTX ligands for enhanced combined cytotoxicity of poly(I:C) nanoplexes.

The antifolate drug methotrexate (MTX) can serve as a dual-functional ligand in antitumoral drug delivery, inducing both a folate receptor mediated cellular uptake and an intracellular cytotoxic action. Bioactivity of MTX however changes by conjugation; the activity can be affected by the hampered intracellular conversion to more potent poly-γ-glutamyl derivatives. Therefore, in a cancer combination therapy approach for the codelivery of cytotoxic dsRNA polyinosinic-polycytidylic acid poly(I:C), a set of molecularly precise oligo(ethanamino)amides were synthesized comprising poly(ethylene glycol) conjugated MTX ligands.

Stability and activity of hydroxyethyl starch-coated polyplexes in frozen solutions or lyophilizates.

Despite their great potential, gene delivery polyplexes have a number of limitations, including their tendency for aggregation in vivo or upon storage. In previous studies, we could show that hydroxyethyl starch (HES)-decoration of polyplexes reduces aggregation in vitro and in vivo. The current study investigates the ability of HES-decoration to improve the stability of polyplexes upon storage as frozen-liquid or lyophilizate, and uses naked polyplexes or PEGylated ones as controls.

The effect of molar mass and degree of hydroxyethylation on the controlled shielding and deshielding of hydroxyethyl starch-coated polyplexes.

PEGylation is currently the gold-standard in shielding cationic DNA-polyplexes against non-specific interaction with blood components. However, it reduces cellular uptake and transfection, in what is known as the "PEG-dilemma". In an approach to solve this problem we developed hydroxyethyl starch (HES)-shielded polyplexes which get deshielded under the action of alpha amylase (AA).

Stabilizing effect of tyrosine trimers on pDNA and siRNA polyplexes.

Nine sequence-defined, polycationic oligomers were synthesized containing motifs of three consecutive tyrosines (Y3) as stabilizing components for pDNA and siRNA polyplex assembly. For pDNA, a combination of terminal oligotyrosines and cysteines was necessary and sufficient for stable polyplex formation. Stable siRNA binding required a combination of terminal cysteines and oligotyrosines, as well as a central hydrophobic modification (oligotyrosines or fatty acids).

Stabilization of polyplexes via polymer crosslinking for efficient siRNA delivery.

The pseudodendritic, biodegradable polymer HD-O, consisting of an OEI800 core with several OEI800 molecules attached to it via 1.6-hexanediol diacrylate linkers, has potent pDNA but poor siRNA delivery ability, due to instability of the resulting siRNA polyplexes. Stabilization of such nanoparticles by crosslinking surface amines of HD-O in the polyplexes with dithiobis-(succinimidylpropionate) (DSP) greatly enhanced gene silencing efficiency.

Nanosized multifunctional polyplexes for receptor-mediated siRNA delivery.

Although our understanding of RNAi and our knowledge on designing and synthesizing active and safe siRNAs significantly increased during the past decade, targeted delivery remains the major limitation in the development of siRNA therapeutics. On one hand, practical considerations dictate robust chemistry reproducibly providing precise carrier molecules. On the other hand, the multistep delivery process requires dynamic multifunctional carriers of substantial complexity.

Structure-activity relationships of siRNA carriers based on sequence-defined oligo (ethane amino) amides.

Sequence defined oligo (ethane amino) amides produced by solid-phase supported synthesis using different building blocks and molecular shapes were tested for structure-activity relationships in siRNA delivery. Efficient reporter gene knockdown was obtained in a variety of cell lines using either branched three-armed structures, or lipid-modified structures with i-shape, T-shape, U-shape configuration. For the majority of structures (apart from U-shapes), the presence of 2 or 3 cysteines was strictly required for polyplex stabilization and silencing activity.

Controlled shielding and deshielding of gene delivery polyplexes using hydroxyethyl starch (HES) and alpha-amylase.

The non-viral delivery of nucleic acids faces many extracellular and intracellular hurdles on the way from injection site to the site of action. Among these, aggregation in the blood stream and rapid elimination by the mononuclear phagocytic system (MPS) represent strong obstacles towards successful development of these promising therapeutic modalities. Even the state-of-the-art solutions using PEGylation show low transfection efficiency due to limited uptake and hindered endosomal escape.

Bioresponsive polymers for the delivery of therapeutic nucleic acids.

Polymers present an interesting option for the delivery of genes and other therapeutic nucleic acids. In the delivery process, the polymeric carriers face many different delivery tasks and different physiological microenvironments. Polymers can be designed to respond to microenvironmental differences with changes in their physio-chemical properties, enabling them to perform individual delivery tasks.