Depletion interactions modulate coupled folding and binding in crowded environments
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Intrinsically disordered proteins (IDPs) abound in cellular regulation. Their interactions are often transitory and highly sensitive to salt concentration and posttranslational modifications. However, little is known about the effect of macromolecular crowding on the kinetics and stability of the interactions of IDPs with their cellular targets. Here, we investigate the influence of crowding on the coupled folding and binding between two IDPs, using polyethylene glycol as a crowding agent across a broad size range. Single-molecule F\"orster resonance energy transfer allows us to quantify several key parameters simultaneously: equilibrium dissociation constants, kinetic association and dissociation rates, and translational diffusion coefficients resulting from changes in microviscosity. We find that the stability of the IDP complex increases not only with the concentration but also with the size of the crowders, in contradiction to scaled-particle theory. However, both the equilibrium and the kinetic results can be explained quantitatively by depletion interactions if the polymeric properties of proteins and crowders are taken into account. This approach thus provides an integrated framework for addressing the complex interplay between depletion effects and polymer physics on IDP interactions in a crowded environment.
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