Self-assembled peptide-based biomaterials provide versatile platforms for biomedical uses, featuring customizable physicochemical properties, biocompatibility, and dynamic capabilities. This self-assembly process is primarily dictated by primary sequence features, such as hydrophobicity, length, and charge, leading to the formation of fibrils and hydrogels. Amphipathic peptides, with alternating polar and hydrophobic residues, are especially effective in forming supramolecular nanofibers stabilized by π-π interactions and hydrogen bonds. Chemical modifications on aromatic side chains are promising for controlling assembly morphology, stability, and biological activity. However, the influence of these substitu... More
Self-assembled peptide-based biomaterials provide versatile platforms for biomedical uses, featuring customizable physicochemical properties, biocompatibility, and dynamic capabilities. This self-assembly process is primarily dictated by primary sequence features, such as hydrophobicity, length, and charge, leading to the formation of fibrils and hydrogels. Amphipathic peptides, with alternating polar and hydrophobic residues, are especially effective in forming supramolecular nanofibers stabilized by π-π interactions and hydrogen bonds. Chemical modifications on aromatic side chains are promising for controlling assembly morphology, stability, and biological activity. However, the influence of these substituents on peptide packing and immunogenicity remains relatively unexplored. Herein, we examine the effect of substituents on benzyl groups attached to short amphipathic peptides. By introducing different electron-donating and withdrawing groups at the para-position of benzyl rings and modifying the chain length connecting the backbone to the aromatic moiety, we observe notable effects on fibril formation, molecular packing, and immunogenicity both in vitro and in vivo. Our results show that subtle chemical modifications are practical tools for designing tailored peptide nanomaterials with promising potential in vaccine delivery, tissue engineering, and regenerative medicine.
