Spatiotemporal Control of Protein Activity through Optogenetic Allosteric Regulation.

Optogenetics offers the potential for mimicking complex spatiotemporal control of enzyme activity down to a subcellular resolution. However, most optogenetic approaches often face significant challenges in integrating multiple capabilities in a single tool applicable to a wide range of target proteins. Achieving precise control over ON/OFF kinetics, ensuring minimum leakiness in the dark, and demonstrating efficient performance in mammalian cells with subcellular precision are some of the most common challenges faced in this field. A promising solution lies in the application of rationally designed light-sensitive domains to allosterically control protein activity. Using that strategy, we generated an optogenetic method combining all the desired features. The approach involves the incorporation of the Light-regulated allosteric switch module (LightR) in the target protein to regulate enzyme activity using blue (465 nm) light. The LightR domain is generated by linking two Vivid (VVD) photoreceptor domains, creating a light-sensitive clamp that can be incorporated into a small flexible loop within the catalytic domain of an enzyme. In its dark state, LightR clamp is open, thus distorting the enzyme's catalytic domain and inactivating it. Upon exposure to blue light, the LightR domain closes and restores the catalytic domain's structure and enzyme activity. In this manuscript, we discuss design strategies to generate a light-regulated protein kinase and demonstrate its control by blue light, reversibility, kinetics, and precise regulation at the subcellular level, enabling tight spatiotemporal precision. Utilizing Src tyrosine kinase as a model, we showcase a protocol for effectively regulating LightR-Src kinase activity. We also demonstrate LightR applicability across different enzyme classes, expanding the utility of the tool system in addressing mechanistic questions of signaling pathways in different diseases.