Turning waste into wealth: Enzyme-activated DNA sensor based on reactant recycle for spatially selective imaging microRNA toward target cells.

Background: Amplified imaging of microRNA (miRNA) in cancer cells is essential for understanding of the underlying pathological process. Synthetic catalytic DNA circuits represent pivotal tools for miRNA imaging. However, most existing catalytic DNA circuits can not achieve the reactant recycling operation in cells and in vivo. Additionally, specificity miRNA imaging in tumor site also is a challenge. Herein, inspired by "turning waste into wealth", we report a DNA sensor for imaging of miRNA in target cells based on apurinic/apyrimidinic endonuclease 1 (APE1)-activated reactant recycling catalytic DNA circuit.

Results: The sensing function of the DNA sensor is suppressed firstly through engineering an apurinic/apyrimidinic (AP) site. In the presence of APE1, the AP site undergoes hydrolysis, thereby activating sensing activity and triggering the strand displacement reaction (SDR) under miRNA assistance. In this catalytic DNA circuit, the next reaction cycle can be initiated when the duplex strand waste products are reverted into active components, which allows it to be performed continuously just consuming fuel DNA without depleting the reactant. Noteworthy, the liposome plays important role in overcome biological barriers for nucleic acid delivery. The amplified miRNA imaging strategy is carried out in vivo by this DNA sensor with reducing off-tumor signal under assistance with APE1, and enhances tumor-to-normal tissue contrast compared with traditional catalytic DNA circuit.

Significance And Novelty: Firstly, APE1-activated reactant recycling catalytic DNA circuit is developed. Secondly, miRNA image in cell and in animal is achieved with high spatial selectivity. Thirdly, the signal-to-background ratio for imaging is improved in vitro and in vivo. Lastly, our strategy provides an automatic yet versatile approach for the development of more efficient and selective DNA circuits capable of differentiating miRNA in cancer cells from those in normal cells, promising to be valuable in cancer diagnosis.