Curated Optogenetic Publication Database

Abstract: Cell signaling regulates a wide range of biological processes including development, homeostasis, and disease. Accessible technologies to precisely manipulate signaling have important applications in basic and translational research. Here, we introduce an optogenetic toolkit comprised of 1) a zebrafish-optimized FGF signaling activator, 2) a single-transcript Nodal signaling activator, and 3) a previously established BMP signaling activator. We thoroughly characterize this suite of tools in zebrafish embryos and show that they provide tunable, light-dependent spatiotemporal control of signaling in vivo. In response to blue light (∼455 nm), receptor kinase domains fused to blue light-dimerizing LOV domains enable robust signaling activation with minimal ectopic activity in the dark or at wavelengths over 495 nm. Optogenetic activation by each tool is pathway-specific and results in increased expression of known target genes. Signaling is activated with rapid on/off kinetics, and activation strength depends on light irradiance. Finally, we demonstrate spatially localized signaling activation with our optimized FGF activator. Together, our results establish this optogenetic toolkit as a potent experimental platform to rapidly, directly, and adjustably activate FGF, BMP, and Nodal signaling in zebrafish embryos.

Abstract: Signaling pathways orchestrate fundamental biological processes, including development, regeneration, homeostasis, and disease. Methods to experimentally manipulate signaling are required to understand how signaling is interpreted in these wide-ranging contexts. Molecular optogenetic tools can provide reversible, tunable manipulations of signaling pathway activity with a high degree of spatiotemporal control and have been applied in vitro, ex vivo, and in vivo. These tools couple light-responsive protein domains, such as the blue light homodimerizing light-oxygen-voltage sensing (LOV) domain, with signaling effectors to confer light-dependent experimental control over signaling. This protocol provides practical guidelines for using the LOV-based bone morphogenetic protein (BMP) and Nodal signaling activators bOpto-BMP and bOpto-Nodal in the optically accessible early zebrafish embryo. It describes two control experiments: A quick phenotype assay to determine appropriate experimental conditions, and an immunofluorescence assay to directly assess signaling. Together, these control experiments can help establish a pipeline for using optogenetic tools in early zebrafish embryos. These strategies provide a powerful platform to investigate the roles of signaling in development, health, and physiology.