ABSTRACT Cyclic nucleotide-modulated channels play major roles in pacemaking activity in heart and brain as well as in olfactory and visual signal transduction in the nervous system. Defects in the functioning of these channels lead to diseases such as epilepsy, cardiac arrhythmia, and color blindness. The overall objective of this grant is to understand how binding of cyclic nucleotides gates (opens/closes) the channels and how other factors such as lipids and proline isomerization modulate this gating. We will accomplish this by combining state-of-the-art techniques: single-particle cryo electron microscopy (cryo-EM) with atomic force microscopy force spectroscopy (AFM-FS), native mass spectrometry (MS), and functional assays like single-channel electrophysiology and stopped flow fluorescence assays of channels incorporated in liposomes. We will employ SthK, a model prokaryotic cyclic nucleotide-modulated channel, and also eukaryotic HCN1 and HCN2 for select sub-aims. Our first aim is to determine the molecular mechanisms for partial agonism and ligand selectivity in SthK. We will determine the structures of specific voltage-sensor SthK mutants that display increased open probability and correlate class averages with the single-channel electrophysiology. To determine the molecular mechanism for ligand selectivity we will use AFM-FS to determine at the single-molecule level the binding kinetics of cAMP and cGMP to either the SthK cyclic nucleotide binding domain alone or in the context of the full-length channel. This will yield the energetics of binding of both cyclic nucleotides and will isolate the contribution of the pore to the binding. This aim will shed light on why cAMP binding does not fully open the SthK channel and why cGMP is an antagonist, although its binding modality to the binding pocket is similar to that of cAMP. Our second aim is to understand how lipids modulate channel activity. We will systematically test the effect of lipids on SthK activity using stopped-flow fluorescence assays and single-channel electrophysiology where channels are in liposomes of controlled composition. We will determine the lipids tightly bound to the channels (both SthK and HCN1) using native MS and determine the mechanism of how they increase activity by perturbing the residues that appear to coordinate these lipid-protein interactions with functional assays. The third aim is to characterize functionally and structurally the regulation of SthK as well as potentially HCN channels by a newly discovered modality: prolyl isomerization of a conserved proline in the cyclic nucleotide binding domain, which appears to be responsible for SthK’s biphasic activation with cAMP. This can be highly impactful, as proline isomerization may turn out to be yet another means to regulate pacemaking activity in the heart and brain. All aims are geared towards unravelling the molecular mechanisms of cyclic nucleotide-modulated channels’ synergistic regulation by ligands,...