PLoS ONE (Jan 2012)

Peptide nanovesicles formed by the self-assembly of branched amphiphilic peptides.

  • Sushanth Gudlur,
  • Pinakin Sukthankar,
  • Jian Gao,
  • L Adriana Avila,
  • Yasuaki Hiromasa,
  • Jianhan Chen,
  • Takeo Iwamoto,
  • John M Tomich

DOI
https://doi.org/10.1371/journal.pone.0045374
Journal volume & issue
Vol. 7, no. 9
p. e45374

Abstract

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Peptide-based packaging systems show great potential as safer drug delivery systems. They overcome problems associated with lipid-based or viral delivery systems, vis-a-vis stability, specificity, inflammation, antigenicity, and tune-ability. Here, we describe a set of 15 & 23-residue branched, amphiphilic peptides that mimic phosphoglycerides in molecular architecture. These peptides undergo supramolecular self-assembly and form solvent-filled, bilayer delimited spheres with 50-200 nm diameters as confirmed by TEM, STEM and DLS. Whereas weak hydrophobic forces drive and sustain lipid bilayer assemblies, these all-peptide structures are stabilized potentially by both hydrophobic interactions and hydrogen bonds and remain intact at low micromolar concentrations and higher temperatures. A linear peptide lacking the branch point showed no self-assembly properties. We have observed that these peptide vesicles can trap fluorescent dye molecules within their interior and are taken up by N/N 1003A rabbit lens epithelial cells grown in culture. These assemblies are thus potential drug delivery systems that can overcome some of the key limitations of the current packaging systems.