Origin of conformational dynamics in a globular protein

Protein structures are dynamic, undergoing motions that can play a vital role in function. However, the link between primary sequence and conformational dynamics remains poorly understood. Here, we studied how conformational dynamics can arise in a globular protein by evaluating the impact of individual core-residue substitutions in DANCER-3, a streptococcal protein G domain β1 variant that we previously designed to undergo a specific mode of conformational exchange that has never been observed in the wild-type protein. Using a combination of solution NMR experiments and molecular dynamics simulations, we demonstrate that only two mutations are necessary to create this conformational exchange, and that these mutations work synergistically, with one destabilizing the native structure and the other allowing two new conformational states to be accessed on the energy landscape. Overall, our results show how dynamics can appear in a stable globular fold, a critical step in the molecular evolution of dynamics-linked functions. Damry et al. evaluates the impact of individual substitutions in primary sequence of a globular protein on its conformational dynamics. They demonstrate that only two mutations in core residues of a streptococcal protein (Gβ1) variant can synergistically create conformational exchange, one destabilizing the native structure while the other allowing two new conformational states to be accessed on the energy landscape.