State-dependent and site-directed photodynamic transformation of HCN2 channel by singlet oxygen

Singlet oxygen ((1)O(2)), which is generated through metabolic reactions and oxidizes numerous biological molecules, has been a useful tool in basic research and clinical practice. However, its role as a signaling factor, as well as a mechanistic understanding of the oxidation process, remains poorly understood. Here, we show that hyperpolarization-activated, cAMP-gated (HCN) channels–which conduct the hyperpolarization-activated current (I(h)) and the voltage-insensitive instantaneous current (I(inst)), and contribute to diverse physiological functions including learning and memory, cardiac pacemaking, and the sensation of pain–are subject to modification by (1)O(2). To increase the site specificity of (1)O(2) generation, we used fluorescein-conjugated cAMP, which specifically binds to HCN channels, or a chimeric channel in which an in-frame (1)O(2) generator (SOG) protein was fused to the HCN C terminus. Millisecond laser pulses reduced I(h) current amplitude, slowed channel deactivation, and enhanced I(inst) current. The modification of HCN channel function is a photodynamic process that involves (1)O(2), as supported by the dependence on dissolved oxygen in solutions, the inhibitory effect by a (1)O(2) scavenger, and the results with the HCN2-SOG fusion protein. Intriguingly, (1)O(2) modification of the HCN2 channel is state dependent: laser pulses applied to open channels mainly slow down deactivation and increase I(inst), whereas for the closed channels, (1)O(2) modification mainly reduced I(h) amplitude. We identified a histidine residue (H434 in S6) near the activation gate in the pore critical for (1)O(2) modulation of HCN function. Alanine replacement of H434 abolished the delay in channel deactivation and the generation of I(inst) induced by photodynamic modification. Our study provides new insights into the instantaneous current conducted by HCN channels, showing that modifications to the region close to the intracellular gate underlie the expression of I(inst), and establishes a well-defined model for studying (1)O(2) modifications at the molecular level.