Optogenetic protein dimerization systems are powerful tools to investigate the biochemical networks that cells use to make decisions and coordinate their activities. These tools, including the improved Light-Inducible Dimer (iLID) system, offer the ability to selectively recruit components to subcellular locations, such as micron-scale regions of the plasma membrane. In this way, the role of individual proteins within signaling networks can be examined with high spatiotemporal resolution. Currently, consistent recruitment is limited by heterogeneous optogenetic component expression, and spatial precision is diminished by protein diffusion, especially over long timescales. Here, we address these challenges within the iLID system with alternative membrane anchoring domains and fusion configurations. Using live cell imaging and mathematical modeling, we demonstrate that the anchoring strategy affects both component expression and diffusion, which in turn impact recruitment strength, kinetics, and spatial dynamics. Compared to the commonly used C-terminal iLID fusion, fusion proteins with large Nterminal anchors show stronger local recruitment, slower diffusion of recruited components, and efficient recruitment over wider gene expression ranges. We also define guidelines for component expression regimes for optimal recruitment for both cell-wide and subcellular recruitment strategies. Our findings highlight key sources of imprecision within light-inducible dimer systems . CC-BY-NC-ND 4.
Neutrophils are key early responders in the innate immune response that use chemotaxis, the directed migration along chemical gradients, to reach sites of infection or inflammation. This process requires integrating inputs from cell surface receptors with the cell's polarity and motility signaling network, in which highly dynamic and interconnected signaling by Rho-family GTPases plays a central role. To understand this fundamentally important behavior, we describe a high-resolution, under-agarose chemotaxis assay for use with neutrophil-like cell lines (HL-60 or PLB-985) or with primary neutrophils. We also describe how to use optical uncaging of chemoattractants to stimulate cells in this assay. These techniques are compatible with epifluorescence, total internal reflection fluorescence (TIRF), and confocal microscopy. Additionally, we cover how to measure the activities of Rho-family GTPases in this context using Förster resonance energy transfer (FRET)-based biosensors. The specific experimental steps outlined in this chapter include how to (1) set up the under-agarose assay, (2) optically pattern chemoattractant gradients, (3) image cells, and (4) conduct basic image analysis for FRET biosensors.
Optogenetic protein dimerization systems are powerful tools to investigate the biochemical networks that cells use to make decisions and coordinate their activities. These tools, including the improved Light-Inducible Dimer (iLID) system, offer the ability to selectively recruit components to subcellular locations, such as micron-scale regions of the plasma membrane. In this way, the role of individual proteins within signaling networks can be examined with high spatiotemporal resolution. Currently, consistent recruitment is limited by heterogeneous optogenetic component expression, and spatial precision is diminished by protein diffusion, especially over long timescales. Here, we address these challenges within the iLID system with alternative membrane anchoring domains and fusion configurations. Using live cell imaging and mathematical modeling, we demonstrate that the anchoring strategy affects both component expression and diffusion, which in turn impact recruitment strength, kinetics, and spatial dynamics. Compared to the commonly used C-terminal iLID fusion, fusion proteins with large N-terminal anchors show stronger local recruitment, slower diffusion of recruited components, and efficient recruitment over wider gene expression ranges. We also define guidelines for component expression regimes for optimal recruitment for both cell-wide and subcellular recruitment strategies. Our findings highlight key sources of imprecision within light-inducible dimer systems and provide tools that allow greater control of subcellular protein localization across diverse cell biological applications.
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