Mohona Sarkar

International audience

An understanding of cellular chemistry requires knowledge of how crowded environments affect proteins. The influence of crowding on protein stability arises from two phenomena, hard-core repulsions and soft (i.e., chemical) interactions. Most efforts to understand crowding effects on protein stability, however, focus on hard-core repulsions, which are inherently entropic and stabilizing. We assessed these phenomena by measuring the temperature dependence of NMR-detected amide proton exchange and used these data to extract the entropic and enthalpic contributions of crowding to the stability of ubiquitin. Contrary to expectations, the contribution of chemical interactions is large and in many cases dominates the contribution from hardcore repulsions. Our results show that both chemical interactions and hard-core repulsions must be considered when assessing the effects of crowding and help explain previous observations about protein stability and dynamics in cells.

Thirty percent of a cell’s volume is filled with macromolecules, and protein chemistry in a crowded environment is predicted to differ from that in dilute solution. We quantified the effect of crowding by globular proteins on the equilibrium thermodynamic stability of a small globular protein. Theory has long predicted that crowding should stabilize proteins, and experiments using synthetic polymers as crowders show such stabilizing effects. We find that protein crowders can be mildly destabilizing. The destabilization arises from a competition between stabilizing excluded-volume effects and destabilizing nonspecific interactions, including electrostatic interactions. This competition results in tunable stability, which could impact our understanding of the spatial and temporal roles of proteins in living systems.