Detection of ATP from “fluorescence” to “enhanced fluorescence” based on metal-enhanced fluorescence triggered by aptamer nanoswitch

Abstract

Herein, we demonstrate a novel approach to detect intracellular adenosine triphosphate (ATP) from “fluorescence” to “enhanced fluorescence” by metal-enhanced fluorescence (MEF), which is an activatable means to amplify fluorescence signal. In the meantime, hybridization chain reaction (HCR) is employed to aggregate DNA on the substrate of MEF, and the length of generated DNA strands is controllable. ATP target molecules specifically bind to aptamer, which is designed as the recognition part of the nanoswitch, and the sticky ends are released. Then, HCR is triggered, bringing Cy7 modified on H1 and H2 close to the surface of gold nanobipyramids (AuNBPs) substrate. The fluorescence signal is amplified with the ATP concentration increasing owing to MEF. Thus, the strategy based on structure-switching aptamer triggering metal-enhanced fluorescence (SATMEF) for Cy7 is designed to detect ATP via “enhanced fluorescence” signals, and the maximum fluorescence enhancement by the approach of SATMEF reaches 5.63-fold. We applied this DNA nanoswitch for quantitative analysis to ATP, and the results show that the intensity of enhanced Cy7 fluorescence is positively correlated with the ATP concentration in the range of 0.2−10 μM, with a detection limit of 35 nM. We believe that the SATMEF for quantitative detection by signal from “fluorescence” to “enhanced fluorescence” provides a new approach for those fluorophores which are superior but difficult to be quenched to construct DNA nanoswitches.