Abstract
AbstractBiomolecules can be sequestered into membrane-less compartments, referred to as biomolecular condensates. Experimental and computational methods have helped define the physical-chemical properties of condensates. Less is known about how the high macromolecule concentrations in condensed phases contribute “solvent” interactions that can remodel the free-energy landscape of other condensate-resident proteins, altering thermally accessible conformations and, in turn, modulating function. Here, we use solution Nuclear Magnetic Resonance (NMR) spectroscopy to obtain atomic resolution insights into the interactions between the immature form of superoxide dismutase 1 (SOD1), which can mislocalize and aggregate in stress granules, and the RNA-binding protein CAPRIN1, a component of stress granules. NMR studies of CAPRIN1:SOD1, focused on both unfolded and folded SOD1 states in mixed phase and de-mixed CAPRIN1-based condensates, establish that CAPRIN1 shifts the folding equilibrium of SOD1 towards the unfolded state through preferential interactions with the unfolded ensemble, with little change to the structure of the folded conformation. Key contacts between CAPRIN1 and the H80-H120 region of unfolded SOD1 are identified, as well as SOD1 interaction sites near both the arginine-rich and aromatic-rich regions of CAPRIN1. Unfolding of immature SOD1 in the CAPRIN1 condensed phase is shown to be coupled to aggregation, while a more stable zinc-bound, dimeric form of SOD1 is less susceptible to unfolding when solvated by CAPRIN1. Our work underscores the impact of the condensate solvent environment on the conformational states of resident proteins and supports the hypothesis that ALS mutations that decrease metal binding or dimerization function as drivers of aggregation in condensates.Significance StatementBiomolecular condensates concentrate proteins and nucleic acids to regulate and perform key biological functions. Although the material properties of these condensates are well-studied, much less is understood about how the structure and dynamics of proteins within them are affected by the high concentration of biomolecules. In this study we have used NMR spectroscopy to study how the folding equilibrium and structural dynamics of the ALS protein SOD1 are modulated inside a condensate formed by CAPRIN1. Our study reveals that the CAPRIN1 condensed phase biases an immature form of SOD1 towards unfolded states that are susceptible to aggregation and provides insights into why this is the case, while a more mature form of the protein is much less affected.
Publisher
Cold Spring Harbor Laboratory
Cited by
2 articles.
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