Cell-Penetrating Cross-ß Peptide Assemblies with Controlled Biodegradable Properties.

Although self-assembled peptide nanostructures (SPNs) have shown potential as promising biomaterials, there is a potential problem associated with the extremely slow hydrolysis rate of amide bonds. Here, we report the development of cell-penetrating cross-ß SPNs with a controllable biodegradation rate. The designed self-assembling ß-sheet peptide incorporating a hydrolyzable ester bond (self-assembling depsipeptide; SADP) can be assembled into bilayer ß-sandwich one-dimensional (1D) fibers similarly to conventional ß-sheet peptides. The rate of hydrolysis can be controlled by the pH, temperature, and structural characteristics of the ester unit. The 1D fiber of the SADP transforms into vesicle-like 3D structures when the hydrophilic cell-penetrating peptide segment is attached to the SADP segment. Efficient cell internalization of the 3D nanostructures was observed, and we verified the intracellular degradation and disassembly of the biodegradable nanostructures. This study illustrates the potential of biodegradable cross-ß SPNs and provides a valuable toolkit that can be used with self-assembling peptides.

Facile synthesis, optical and conformational characteristics, and efficient intracellular delivery of a peptide-DNA conjugate.

Covalent conjugation of disparate peptide and oligonucleotide biomacromolecular species produces peptide-oligonucleotide conjugates (POCs), which are interesting molecules with great potential for use in diverse bioapplications. However, peptide-oligonucleotide conjugation methods are not well established, and the intracellular delivery efficacy of POCs is debatable. Here, we describe a simple method for the synthesis and purification of POCs. When peptides are carefully designed to have a near-neutral charge state, a relatively hydrophobic polarity, and receptor-targeting ligands, synthesis and purification become highly efficient and straightforward. UV-vis, fluorescence, and circular dichroism studies show that both types of molecules mutually influence each other, changing their optical and conformational characteristics in the context of POCs. The combined effect of peptide design strategy, targeting ligands, and relatively hydrophobic property, enables the efficient cellular delivery of POCs.

Bioinspired self-assembled peptide nanofibers with thermostable multivalent α-helices.

The stabilization of peptide's active conformation is a critical determinant of its target binding efficiency. Here we present a structure-based self-assembly strategy for the design of nanostructures with multiple and thermostable α-helices using bioinspired peptide amphiphiles. The design principle was inspired by the oligomerization of the human immunodeficiency virus type-1 (HIV-1) Rev protein. Our goal was to find a strategy to modify the Rev protein into a chemically manageable self-assembling peptide while stabilizing its α-helical structure. Instead of using cyclic peptides for structure stabilization, this strategy utilizes the pseudocyclization for helix stabilization. The self-assembly induced stabilization of α-helical conformation could be observed, and the α-helices were found to be stable even at high temperature (at least up to 74 °C). Conjugation of a hydrophobic alkyl chain to the Rev peptide was crucial for forming the self-assembled nanostructures, and no nanostructures could be obtained without this modification. Because chemical modifications to the α-helical peptide domain can be avoided, potentially any α-helical peptide fragment can be grafted into this self-assembling peptide scaffold.