Abstract
Early interactions between viruses and live cells are difficult to resolve due to rapid extracellular motion, 3D nature of the cell membrane, and the fast, nanoscale interactions involved. While actin is a central regulator of viral entry, direct observations of actin-aided trafficking have been restricted to membrane protrusions on glass surfaces given the limitations of conventional methods. Here, high-speed 3D Tracking and Imaging microscopy (3D-TrIm) is integrated with highly photostable StayGold-labeled SARS-CoV-2 virus-like particles to capture long-term, high-resolution single-virus trajectories in live cells. This approach revealed distinct regimes of viral dynamics, including extracellular diffusion, protrusion-based surfing, and an unreported linear trafficking mode along the plasma membrane that precedes viral internalization. This work demonstrates that this membrane trafficking is actin-driven and positively correlated with ACE2 expression. These findings reveal new actin exploitation by viruses and demonstrate the utility of 3D-TrIm for dissecting dynamic virus-cell interactions at high spatiotemporal resolution.