Abstract
AbstractThe crowded interior of a living cell makes experiments on simplerin vitrosystems attractive. Although these reveal interesting phenomena, their biological relevance can be questionable. A topical example is the phase separation of intrinsically-disordered proteins into biomolecular condensates, which is proposed to underlie the membraneless compartmentalisation of many cellular functions. How a cell reliably controls biochemical reactions in compartments open to the compositionally-varying cytoplasm is an important question for understanding cellular homeostasis. Computer simulations are often used to study the phase behaviour of model biomolecular condensates, but the number of relevant parameters explodes as the number of protein components increases. It is unfeasible to exhaustively simulate such models for all parameter combinations, although interesting phenomena are almost certainly hidden in the jungle of their high-dimensional parameter space. Here we have studied the phase behaviour of a model biomolecular condensate in the presence of a polymeric crowding agent. We used a novel compute framework to execute dozens of simultaneous simulations spanning the protein/crowder concentration space. We then combined the results into a graphical representation for human interpretation, which provided an efficient way to search the model’s high-dimensional parameter space. We found that steric repulsion from the crowder drives a near-critical system across the phase boundary, but the molecular arrangement within the resulting biomolecular condensate is rather insensitive to the crowder concentration and molecular weight. We propose that a cell may use the local cytoplasmic concentration to assist formation of biomolecular condensates, while relying on the dense phase reliably providing a stable, structured, fluid milieu for cellular biochemistry despite being open to its changing environment.
Publisher
Cold Spring Harbor Laboratory