Sequential enzyme-activated macrotheranostic probe for selective tumor mitochondria targeting

Subcellular organelle targeted imaging and therapy are of enormous interest in cancer theranostics. However, the lack of tumor-selective organelle targeting has compromised their efficacy and safety. In this work, we found that the near-infrared (NIR) fluorophore hemicyanine (CyNH2) can selectively target mitochondria with strong cytotoxicity through decreasing the mitochondrial membrane potential and increasing the intracellular reactive oxygen species (ROS) levels. A macrotheranostic probe (denoted as PLCy) based on conjugating CyNH2 with an acetylated lysine group was developed with masked fluorescence and cytotoxicity, which could both be unmasked through sequential activation by cancer cells overexpressing histone deacetylases (HDACs) and cathepsin L (CTSL) enzymes for selective cancer cell mitochondria-targeted imaging and therapy. In vitro and in vivo studies confirmed that the specific fluorescence turn-on and toxicity were restored in cancer cells and efficiently inhibited tumor growth. This macrotheranostic probe with sequential enzyme activation and mitochondrial targeting is expected to have promising applications in imaging-guided cancer therapy with high specificity and efficiency. Statement of significance To improve the targeting efficiency and enhance the anti-cancer activities of macrotheranostic probe. We designed macrotheranostic probe PLCy that can be activated via sequential enzymes for selective tumor mitochondria targeting. More importantly, the activated CyNH2 can decrease the mitochondrial membrane potential and elevate the reactive oxygen species level in cancer cells without light irradiation, which can further induce apoptosis of tumor cells for chemotherapy. Therefore, the use of sequential enzyme activation and mitochondria targeting strategies in the context of enzymatic activation may provide a general strategy for organelle-targeted imaging and therapy with high specificity and efficiency.