Multi-domain proteins or intrinsically disordered proteins (IDPs) often undergo liquid-liquid phase separation (LLPS) and form membraneless organelles or protein condensates. Such compartmentalization is considered critical in many cellular processes dynamically modulated by various external signals. However, molecular mechanisms underlying potential regulatory functions of the protein condensates remain obscure due to a limited understanding of the driving forces for their assembly. Here we propose isothermal titration calorimetry (ITC) as an efficient analytical tool to dissociate condensates and measure the corresponding dissociation heat. Subsequent analysis of the initial dissociation heat as a function of total protein concentration allows simple and accurate determination of the thermodynamic parameters for cooperative condensate formations including the dissociation (or condensation) enthalpy and the critical protein concentration. By performing systematic simulations, we further demonstrate that the initial heat analysis is sufficiently robust to quantitatively dissect protein condensates with a broad range of thermodynamic properties. Therefore, our proposed method analyzing the initial heat measured in dissociation ITC provides opportunities to further scrutinize the thermodynamic quantities as functions of solution variables to explore the molecular driving forces of LLPS.
Keywords: Biomolecular condensates; Critical protein concentration; Dissociation enthalpy; Initial heat analysis; Isothermal titration calorimetry; Liquid liquid phase separation.
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