Integrating energy calculations with functional assays to decipher the specificity of G-protein inactivation by RGS proteins

The diverse RGS protein family is responsible for the precise timing of G-protein signaling. To understand how RGS protein structure encodes their common ability to inactivate G-proteins and their selective G-protein recognition, we integrated structure-based energy calculations with biochemical measurements of RGS protein activity. We revealed that, in addition to previously identified conserved residues, RGS proteins contain another group of variable modulatory residues, which reside at the periphery of the RGS-domain–G-protein interface and fine-tune G-protein recognition. Mutations of modulatory residues in high-activity RGS proteins impaired RGS function, whereas redesign of low-activity RGS proteins in critical modulatory positions yielded complete gain-of-function. Therefore, RGS proteins combine a conserved core interface with peripheral modulatory residues to selectively optimize G-protein recognition and inactivation. Finally, we show that our quantitative framework for analyzing protein-protein interactions can be extended to analyze interaction specificity across other large protein families.