Endogenous Adenosine Triphosphate-Assisted Three-Dimensional DNA Walker Assembled on Soft Nanoparticles for Intracellular MicroRNA Imaging.

Abstract

DNA walkers, a sophisticated type of nanomachines, exhibit intelligent application in biosensing with high programmability and flexibility but usually need additional auxiliary driving force, particularly when walking on hard surfaces. Herein, we construct a three-dimensional (3D) DNA walker on the soft surface of DNA nanospheres (DSs) by using a single-stranded DNA (ssDNA), which is powered by endogenous adenosine triphosphate (ATP) of live cells, so as to sensitively image microRNA (miRNA) in the tumor microenvironment. When the DS walker enters into live cells, miR-21, a general overexpressed biomarker in cancer cells, binds with the blocking strand (B), releasing the walking strand (W) and triggering an ATP-propelled walking reaction. The walking of the DS walker then generates an increasing Cy3 fluorescence signal that indicates the content of miR-21 with about 2.73-fold increase in sensitivity and about 157-fold decrease in the detection limit. Notably, the assembly of the DS walker on soft nanoparticles needs just an easy hybridization process, which facilitates the operation. Meanwhile, this endogenous ATP-powered 3D DNA walker walking on the soft surface performs real-time in situ imaging of miR-21 in live cells, which not only avoids the complex cell treatment and signal error induced by additional auxiliary factors, but also shows high promise of designing programmable DNA nanomachines.