Neurons have ion channels that are directly gated by voltage, ligands and temperature but not by light. Using structure-based design, we have developed a new chemical gate that confers light sensitivity to an ion channel. The gate includes a functional group for selective conjugation to an engineered K + channel, a pore blocker and a photoisomerizable azobenzene. Long-wavelength light drives the azobenzene moiety into its extended trans configuration, allowing the blocker to reach the pore. Short-wavelength light generates the shorter cis configuration, retracting the blocker and allowing conduction. Exogenous expression of these channels in rat hippocampal neurons, followed by chemical modification with the photoswitchable gate, enables different wavelengths of light to switch action potential firing on and off. These synthetic photoisomerizable azobenzene-regulated K + (SPARK) channels allow rapid, precise and reversible control over neuronal firing, with potential applications for dissecting neural circuits and controlling activity downstream from sites of neural damage or degeneration.Natural photoreceptive proteins, such as rhodopsin, have a covalently attached chromophore that directly activates the protein on exposure to light. Several strategies have been used to enable light regulation of proteins that are not intrinsically light sensitive. Light can be used indirectly to activate receptor proteins, for example, by making a ligand available from a caged precursor 1 . Light can also be used to directly photoisomerize a synthetic molecule that is covalently attached to a protein, thereby imposing conformational changes 2,3 . We have combined these ideas by synthesizing a photoisomerizable tether that attaches a specific ligand on a protein near its normal binding site. Photoswitching of the tethered ligand rapidly regulates its ability to reach its binding site, thereby switching the protein on and off without causing unnatural conformational changes. Photoswitchable tethered ligands can be agonists (for example for nicotinic acetylcholine receptors 4 ), antagonists, or other regulators of protein function. We have applied this general design principle to an ion channel, where the chosen ligand is a blocker of the channel's pore.
NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript diffusion kinetics. Recently, the exogenous expression of genes encoding ion channels has been used to influence electrical activity in specific neurons 7-9 , but the onset and reversal of gene expression is slow. A modification of this technique, in which a receptor from one species is introduced into another that lacks a natural ligand, dramatically improves temporal control 10,11 , but this approach still relies on a diffusible ligand whose time course of removal limits reversibility. Finally, photic regulation has been conferred on neurons by introducing a rhodopsin-based signal transduction cascade 12 . This technique requires coordinated exogenous expression of three different genes and produ...
