Cellularly-Retained Fluorogenic Probes for Sensitive Cell-Resolved Bioactivity Imaging

Here, we develop a general design for high-quality fluorogenic activity probes to quantify biological processes in live cells, by creating a scaffold that efficiently generates cell-retained bright fluorescent soluble products upon reaction with biochemical targets. Live cell probes must be designed to be membrane-permeable; but that often means that their fluorophore products are similarly permeable, resulting in rapid signal loss from the activating cell: which limits their cell-by-cell resolution as well as their sensitivity for quantifying low-turnover processes. Current strategies to retain fluorescent products within cells usually disrupt native biology: e.g. by non-specific alkylation or solid precipitation. Here, scanning charge- and polarity-based approaches to trigger cell retention, we developed a bright fluorogenic rhodol scaffold Tra ppable G reen ( TraG ) that balances all key requirements for signal integration (rapid probe entry, but effective product retention, across a variety of cell lines) and is easily adaptable to quantify many target types (shown here with probes for GSH, TrxR, and H ₂ O ₂ ). The simple and rugged TraG scaffold can now permit straightforward elaboration to a range of cell-retained enzyme activity probes, that enable more accurate cell-resolved imaging as well as higher-sensitivity integration of low-turnover processes, without the drawbacks of alkylation or precipitation-based strategies.