Live cell imaging has emerged as a powerful means to study viral replication dynamics and identify sites of virus-host interactions. Multivariate aspects of viral replication cycles yield challenges inherent to handling large, complex imaging data sets. Herein, we describe the design and implementation of an automated, imaging-based strategy, “Human Immunodeficiency Virus Red-Green-Blue” (HIV RGB), for deriving comprehensive single-cell measurements of HIV-1 unspliced (US) RNA nuclear export, translation, and bulk changes to viral RNA and protein (HIV-1 Rev and Gag) subcellular distribution over time. Differentially tagged fluorescent viral RNA and protein species are recorded using multicolor long-term (>24h) time-lapse video microscopy, followed by image processing using a new open-source computational imaging workflow dubbed nuclear ring segmentation analysis and tracking (NR-SAT) based on ImageJ plugins integrated into the Konstanz Information Miner (KNIME) analytics platform. We describe a typical HIV RGB experimental set-up, detail the image acquisition and NR-SAT workflow accompanied by a step-by-step tutorial, and demonstrate a use case wherein we test the effects of perturbing subcellular localization of the Rev protein, which is essential for viral US RNA nuclear export, on the kinetics of HIV-1 late-stage gene regulation. Collectively, HIV RGB represents a powerful platform for single-cell studies of HIV-1 post-transcriptional RNA regulation. Moreover, we discuss how similar NR-SAT-based design principles and open-source tools might be readily adapted to study a broad range of dynamic viral or cellular processes.
NR-SAT Example output:
