Identification of communication networks in Spo0F: a model for phosphorylation‐induced conformational change and implications for activation of multiple domain bacterial response regulators

Fundamental to understanding the mechanism by which phosphorylation activates bacterial signal transduction response regulator proteins is the identification of regions and residues that are responsible for the phosphorylation‐induced conformational change. Here we review results from structural and protein dynamics investigations, and combine them with mutagenesis studies on the response regulator protein Spo0F to suggest a model in which a network of buried and surface residues link surface regions required for protein:protein interactions to the site of phosphorylation. The network described for Spo0F may provide pathways through which information is transmitted from the site of phosphorylation, propagating a conformational change many angstroms away. The general applicability of the communication network model for all bacterial response regulator proteins is discussed.