RNA plays a fundamental, pervasive role in cellular physiology, through the maintenance and controlled readout of all genetic information, a functional landscape we are only beginning to understand.In particular, the cellular mechanisms for the spatiotemporal control of the plethora of RNAs are still poorly understood.Intracellular single-molecule fluorescence microscopy provides a powerful emerging tool for probing the pertinent biophysical and biochemical parameters that govern cellular RNA functions, including those of protein-encoding mRNAs.Yet progress has been hampered by the scarcity of high-yield, efficient methods to fluorescently label RNA molecules without the need to drastically increase their molecular weight through artificial appendages that may result in altered behavior.Herein, we employ a series of in vitro enzymatic techniques to efficiently, extensively and in high-yield, incorporate chemically modified nucleoside triphosphates into a transcribed messenger RNA body, between its body and tail (BBT), or randomly throughout the poly(A) tail (tail).Of these, BBT and tail modified strategies proved the most promising methods to functionally label messenger RNA and single-particle track their behaviors using our in-house single-molecule assay: intracellular single-molecule high resolution localization and counting (iSHiRLoC).From this research also was spawned a novel method to anchor an RNA to the actin cytoskeleton for the study of long-term interactions within a cellular context, termed: Gene-Actin Tethered Intracellular Co-tracking Assay (GATICA).Here, biotinylated RNA is tethered to the actin surface, either through complexation with a streptavidin coupled to a biotinylated phalloidin molecule or actin protein.Taken together, this body of work represents strategies for the labeling and visualizing, both freely diffusing and actin tethered, long-RNAs and their interactome in real-time.
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Fluorescent Labeling, Co-Tracking, and Quantification of RNA In Cellulo.