Abstract
Biomolecular condensates, often formed through liquid-liquid phase separation, are dynamic cellular compartments. Here, we demonstrate that a wide range of fluorescently tagged proteins undergo inadvertent, condensate-mediated crosslinking, resulting in rapid solidification of condensates under common fluorescence imaging conditions. The process is driven by excitation-induced, short-lived reactive oxygen species (ROS), whose otherwise limited crosslinking potential becomes uniquely enabled in the dense phase. In live cells, excitation-induced ROS potently trigger stress granule formation, while the ROS-driven solidification of condensates is modulated by compartment-dependent antioxidant buffering. Our findings demonstrate that condensates create a distinct environment that enables ROS chemistry unlikely to occur in the bulk cytosol. Furthermore, the cellular redox level can be a general regulator of condensate rheology. Beyond biological insights, our findings underscore the need for scrutiny when examining fluorophore-labeled condensates.