Nucleation dynamics of a model biomolecular liquid.
J Chem Phys
; 160(21)2024 Jun 07.
Article
en En
| MEDLINE
| ID: mdl-38847600
ABSTRACT
Liquid-liquid phase separation in biology has recently been shown to play a major role in the spatial control of biomolecular components within the cell. However, as they are phase transitions, these processes also display nontrivial dynamics. A model phase-separating system of DNA nanostars provides unique access to nucleation physics in a biomolecular context, as phase separation is driven near room temperature by highly thermo-responsive DNA hybridization and at modest DNA concentrations. By measuring the delay time for phase-separated droplets to appear, we demonstrate that the dynamics of DNA nanostar phase separation reflect that of a metastable binary mixture of patchy particles. For sufficiently deep temperature quenches, droplets undergo spinodal decomposition and grow spontaneously, driven by Brownian motion and coalescence of phase-separated droplets, as confirmed by comparing experimental measurements to particle-based simulations. Near the coexistence boundary, droplet growth slows substantially, indicative of a nucleation process. The temperature dependence of droplet appearance times can be predicted by a classical nucleation picture with mean field exponents and demonstrates that a theory previously used to predict equilibrium phase diagrams can also distinguish spinodal and nucleation dynamical regimes. These dynamical principles are relevant to behaviors associated with liquid-liquid phase separating systems, such as their spatial patterning, reaction coupling, and biological function.
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1
Colección:
01-internacional
Banco de datos:
MEDLINE
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Idioma:
En
Revista:
J Chem Phys
Año:
2024
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Article
País de afiliación:
Estados Unidos