Multicompartment micelle-structured peptide nanoparticles: a new biocompatible gene- and drug-delivery tool.

Self-assembled, biodegradable materials that embed fragile, soluble, or insoluble compounds of therapeutic interest have potential use as drug delivery systems. The bead-forming peptide Ac-X3-gT can embed hydrophobic and hydrophilic payloads. Loaded peptide beads were internalized by human acute monocytic leukemia cell line (THP-1) macrophages, THP-1 monocytes, and hepatocellular carcinoma cells (Huh7). Furthermore, paclitaxel and doxorubicin coencapsulated in the peptide beads were delivered to THP-1 monocytes, causing a decrease in cell viability due to the activity of the anticancer drugs. In addition to the bead-forming peptide Ac-X3-gT, the use of a positively charged peptide analogue increased the RNA/DNA embedding efficiency to 99% by charge compensation and micellar complexation. Internalization of the resulting gene delivery systems by Huh7 cells led to specific gene silencing either by embedded small interfering RNA or by plasmid-encoding small hairpin RNA delivered in cells. The new class of purely peptidic material caused no measurable toxicity during in vitro experiments, thereby indicating potential use as a drug delivery system for multidrug delivery and gene therapy.

Self-assembled peptide beads used as a template for ordered gold nanoparticle superstructures.

Using peptide-based materials to tailor self-assembled, nano-scaled hybrid materials with potentially high biocompatibility/biodegradability is gaining importance in developing a broad range of new applications, in areas such as diagnostics and medicine. Here, we investigated how the self-assembly ability of amphiphilic peptides can be used to create organized inorganic materials, i.e. gold nanoparticles. A bead-forming, purely peptidic amphiphile Ac-[K(Ac)]3-[W-l]3-W-NH2, containing acetylated (Ac) l-lysine (K), l-tryptophan (W) and d-leucine (l), was C-terminally modified with a l-cysteine (C) and linked to gold nanoparticles. Subsequent peptide-driven self-assembly of the peptide-coated gold nanoparticles with increasing water content led to controlled aggregation of the gold-core micelles, forming composite peptide-gold superstructures. The individual gold nanoparticles did not agglomerate but were separated from each other by a peptide film within the composite material, as revealed by electron microscopy studies. Structural investigation on 2D template-stripped gold demonstrated the ability of the peptides to form self-assembled monolayers. Structural elements of ß-turns and weak hydrogen bonding of the hydrophobic moiety of the peptide were evident, thereby suggesting that the secondary structure remains intact.