Mapping the structure and conformational movements of proteins with transition metal ion FRET

Visualizing conformational dynamics in proteins has been difficult, and the atomic-scale motions responsible for the behavior of most allosteric proteins are unknown. Here, we report that FRET between a small fluorescent dye and a nickel ion bound to a di-histidine motif can be used to monitor small structural rearrangements in proteins. This method provides several key advantages over classical FRET including the ability to measure the dynamics of close range interactions, the use of small probes with short linkers, a low orientation dependence, and the ability to add and remove unique tunable acceptors. We used this ‘transition metal ion FRET’ approach along with x-ray crystallography to determine the structural changes of the gating-ring of the mouse hyperpolarization-activated cyclic nucleotide-regulated ion channel HCN2. Binding of cAMP to the isolated carboxyl-terminal region of HCN2 caused a structural rearrangement involving a movement of the C-helix towards the β-roll of the cAMP-binding domain and a movement of the F′ helix of the C-linker, along with a stabilization of the secondary structure of the helices. Our results suggest a general model for the conformational switch in the cyclic nucleotide-binding site of cyclic nucleotide-regulated ion channels.