Optogenetic Control of RhoA to Probe Subcellular Mechanochemical Circuitry

Q3 Biochemistry, Genetics and Molecular Biology

Current Protocols in Cell Biology Pub Date : 2020-02-07 DOI:10.1002/cpcb.102

Kate E. Cavanaugh, Patrick W. Oakes, Margaret L. Gardel

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引用次数: 8

Abstract

Spatiotemporal localization of protein function is essential for physiological processes from subcellular to tissue scales. Genetic and pharmacological approaches have played instrumental roles in isolating molecular components necessary for subcellular machinery. However, these approaches have limited capabilities to reveal the nature of the spatiotemporal regulation of subcellular machineries like those of cytoskeletal organelles. With the recent advancement of optogenetic probes, the field now has a powerful tool to localize cytoskeletal stimuli in both space and time. Here, we detail the use of tunable light-controlled interacting protein tags (TULIPs) to manipulate RhoA signaling in vivo. This is an optogenetic dimerization system that rapidly, reversibly, and efficiently directs a cytoplasmic RhoGEF to the plasma membrane for activation of RhoA using light. We first compare this probe to other available optogenetic systems and outline the engineering logic for the chosen recruitable RhoGEFs. We also describe how to generate the cell line, spatially control illumination, confirm optogenetic control of RhoA, and mechanically induce cell-cell junction deformation in cultured tissues. Together, these protocols detail how to probe the mechanochemical circuitry downstream of RhoA signaling. © 2020 by John Wiley & Sons, Inc.

Basic Protocol 1: Generation of a stable cell line expressing TULIP constructs

Basic Protocol 2: Preparation of collagen substrate for imaging

Basic Protocol 3: Transient transfection for visualization of downstream effectors

Basic Protocol 4: Calibration of spatial illumination

Basic Protocol 5: Optogenetic activation of a region of interest

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光遗传学控制RhoA探测亚细胞机械化学回路

蛋白质功能的时空定位对于从亚细胞到组织尺度的生理过程至关重要。遗传和药理学方法在分离亚细胞机制所需的分子成分方面发挥了重要作用。然而，这些方法在揭示亚细胞机制(如细胞骨架细胞器)的时空调节本质方面能力有限。随着光遗传学探针的最新进展，该领域现在有了一个强大的工具来定位空间和时间上的细胞骨架刺激。在这里，我们详细介绍了可调光控相互作用蛋白标签(TULIPs)在体内操纵RhoA信号的使用。这是一种光遗传二聚化系统，可以快速、可逆、有效地将细胞质RhoGEF引导到质膜上，利用光激活RhoA。我们首先将该探针与其他可用的光遗传系统进行比较，并概述了所选可招募的rhogef的工程逻辑。我们还描述了如何在培养组织中产生细胞系，空间控制照明，确认RhoA的光遗传控制，以及机械诱导细胞-细胞连接变形。总之，这些协议详细说明了如何探测RhoA信号下游的机械化学电路。©2020 by John Wiley &基本方案1:生成表达TULIP的稳定细胞系基本方案2:制备用于成像的胶原底物基本方案3:用于可视化下游效应的瞬时转染基本方案4:空间照明的校准基本方案5:感兴趣区域的光遗传学激活

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current Protocols in Cell Biology Biochemistry, Genetics and Molecular Biology-Cell Biology

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期刊介绍： Developed by leading scientists in the field, Current Protocols in Cell Biology is an essential reference for researchers who study the relationship between specific molecules and genes and their location, function and structure at the cellular level. Updated every three months in all formats, CPCB is constantly evolving to keep pace with the very latest discoveries and developments.