Abstract
Eukaryotic cells can achieve spatiotemporal control over biological processes through biomolecular condensate assemblies. Biocondensates form a complex network driven by electrostatic interactions, with residues such as Arginine (Arg) and Lysine (Lys) contributing to these interactions. Both Arg and Lys have the same formal charge, but the different structures produce different complexation behavior. How these two distinct residues can produce different physical condensate properties is poorly understood. Using two-dimensional infrared spectroscopy (2D IR) in concert with molecular dynamics (MD) simulations on model condensates of either poly-Arg or poly-Lys, we demonstrate that Arg-based condensates show significantly slower hydration dynamics. We rationalize the differences observed in dynamics by characterizing structures and local interactions. Simulations show that poly-Arg forms a more compact and dense structure compared to poly-Lys-based condensates. These results highlight the role of strong electrostatic and H-bonding interactions in determining the local condensate environment.