Curated Optogenetic Publication Database

Abstract: Inducible translocation to subcellular compartments is a common strategy for protein switches that control a variety of cell behaviors. However, existing switches achieve translocation through induced dimerization, requiring constitutive anchoring of one component into the target compartment and optimization of relative expression levels between the two components. We present a simpler, single-component strategy called Avidity-assisted targeting (Aviatar). Aviatar achieves translocation with only a single protein by converting low-affinity monomers into high-avidity assemblies through inducible clustering. We demonstrated the Aviatar concept and its generality using optogenetic clustering to drive translocation to the plasma membrane, endosomes, golgi, endoplasmic reticulum, and microtubules using binding domains for lipids or endogenous proteins that were specific to those compartments. Aviatar recruitment regulated actin polymerization at the cell periphery and revealed compartment-specific signaling of receptor tyrosine kinase fusions associated with cancer. Finally, GFP-targeting Aviatar probes allowed inducible localization to any GFP-tagged target, including endogenously tagged stress granule proteins. Aviatar is a straightforward platform that can be rapidly adapted to a broad array of targets without the need for their prior modification or disruption.

Abstract: Biomolecular networks can dynamically encode information, generating time-varying patterns of activity in response to an input. Here we find that dynamic encoding can also be performed by individual proteins. BcLOV4 is an optogenetic protein that uniquely displays pulsatory activation in response to a step input of light, and response dynamics can be shaped by both light and temperature. However, how the BcLOV4 protein generates this step-to-pulse response is not understood. Here we combined live cell imaging and simulations to find that the activity pulse results from an intramolecular incoherent feedforward loop (IFFL) implemented by competitive interactions between protein domains that separately respond to light or temperature. We identified these light- and temperature-sensitive regions and found that they implement the IFFL by competitively caging an activation region. Structural and sequence analysis revealed temperature-responsive regions of BcLOV4 which allowed experimental tuning of activation dynamics and suggested that tuning has also occurred throughout evolution. These findings enabled the generation of more thermostable optogenetic tools and identified a modular thermosensitive domain that endowed thermogenetic control over unrelated proteins. Our findings uncover principles of dynamic and combinatorial signal processing in individual proteins that will fuel development of more sophisticated and compact synthetic systems.

Abstract: Biomolecular condensates appear throughout cell physiology and pathology, but the specific role of condensation or its dynamics is often difficult to determine. Optogenetics offers an expanding toolset to address these challenges, providing tools to directly control condensation of arbitrary proteins with precision over their formation, dissolution, and patterning in space and time. In this review, we describe the current state of the field for optogenetic control of condensation. We survey the proteins and their derivatives that form the foundation of this toolset, and we discuss the factors that distinguish them to enable appropriate selection for a given application. We also describe recent examples of the ways in which optogenetic condensation has been used in both basic and applied studies. Finally, we discuss important design considerations when engineering new proteins for optogenetic condensation, and we preview future innovations that will further empower this toolset in the coming years.