Hierarchical structural organization in bioinspired peptide coacervate microdroplets

Abstract

ABSTRACTThis study explores the dynamic and hierarchical structural organization of peptide coacervate microdroplets at the meso-to atomic-scale resolution using a combination of Transferred Nuclear Overhauser Effect Spectroscopy (TrNOESY), Small Angle Neutron Scattering (SANS), and confocal microscopy. Dynamic interactions driving the self-association of peptide clusters are revealed, highlighting the critical roles of interacting residues. These phase-separating model peptides form small oligomers at low pH, which aggregate into larger clusters at neutral pH. These clusters organize into a porous network within the droplets, facilitating size-selective cargo sequestration. The findings underscore the significance of the dynamic spatio-temporal properties of peptide-based coacervates, contributing to our understanding of phase separation at the atomic and molecular levels. Critically, this approach enables the investigation of coacervate structures in their native state, offering insights into the physical and dynamic interactions governing droplet formation and cargo encapsulation.TOC