Fine-tuning of proton sponges by precise diaminoethanes and histidines in pDNA polyplexes.

The cationizable nature of 'proton-sponge' transfection agents facilitates pDNA delivery in several steps. Protonated amines account for electrostatic DNA binding and cellular uptake, buffering amines mediate polyplex escape from acidifying intracellular vesicles. As demonstrated with a sequence-defined library of oligo(ethanamino)amides containing selected oligoethanamino acids and histidines, the total protonation capacity as well as the cationization pH profile within the endolysosomal range have critical impact on gene transfer. Building blocks with even numbered amine groups (Gtt, Sph) exhibited higher total endolysosomal buffer capacity than odd number (Stp) analogs. Within the endolysosomal range, Gtt has the highest buffer capacity around pH5, whereas Stp has its maximum around pH7. Histidines increased the total buffer capacity, resulted in a more continuous cationization pH profile and greatly improved transgene expression in vitro and in vivo. Using receptor targeted and polyethylene glycol shielded polyplexes, better endosomal escape and >100-fold enhanced transfection was detected. FROM THE CLINICAL EDITOR: Proton-sponge transfection agents for pDNA delivery are characterized in this study, demonstrating over 100-fold enhanced transection and better endosomal escape by using receptor targeted and polyethylene glycol shielded polyplexes.

Sequence-defined four-arm oligo(ethanamino)amides for pDNA and siRNA delivery: Impact of building blocks on efficacy.

Cationic oligomers were assembled by solid-phase supported synthesis in few coupling steps based on C-terminal alanine and two lysine branchings, followed by elongation of the four arms with two to five repeats of artificial oligoamino acids containing the 1,2-diaminoethane motif, and ended by N-terminal cysteines or alanines. These sequence-defined oligomers, containing between 28 and 68 protonatable nitrogens, were evaluated for complex formation with plasmid DNA (pDNA) and short interfering RNA (siRNA), followed by reporter gene transfer and gene silencing experiments in Neuro2A cells. By two simple variations, the pDNA gene transfer activity could be thousand-fold improved, exceeding the gold standard linear PEI up to >50-fold. Firstly, the N-terminal cysteines introduced for bioreversible stabilization of polyplexes by internal disulfide links after complex formation greatly enhanced gene transfer. Secondly, variation of the artificial oligoamino acid building blocks containing either triethylene tetramine (Gtt), tetraethylene pentamine (Stp), or pentaethylene hexamine (Sph) disclosed a clear ranking in the order of Sph>Stp>>Gtt for both pDNA compaction and transfection activity. Extending the chain lengths of the arms beyond three building blocks had marginal impact on the performance. For the much smaller siRNA cargo, polyplex stabilization by cysteine disulfides presents a strict requirement. Sph and Stp based cysteine-ended four-arms displayed similar binding activity, with Stp providing best gene silencing efficiency.