Organelle-Specific Photoactivation of DNA Nanosensors for Precise Profiling of Subcellular Enzymatic Activity

Understanding of the functions of enzymes in diverse cellular processes is important, but the design of sensors with controllable localization for in situ imaging of subcellular levels of enzymatic activity is particularly challenging. We introduce herein a spatiotemporally controlled sensor technology that permits in situ localization and photoactivated imaging of human apurinic/apyrimidinic endonuclease 1 (APE1) within an intracellular organelle of choice (e.g., mitochondria or nucleus). The hybrid sensor platform is constructed by photoactivatable engineering of a DNA-based fluorescent probe and further combination with an upconversion nanoparticle and a specific organelle localization signal. Controlled localization and NIR-light-mediated photoactivation of the sensor on demand effectively constrains the imaging signal to the organelle of interest, with improved subcellular resolution. We further demonstrate the application of the nanosensors for the imaging of subcellular APE1 translocation in response to oxidative stress in live cells.

Automated summary

The technology allows for in situ imaging of enzymatic activity in specific organelles through controlled localization and photoactivation, leading to improved subcellular resolution.