DNA-capped Silver Nanoflakes as Fluorescent Nanosensor for Highly Sensitive Imaging of Endogenous H2S in Cell Division Cycles

Biochemical sensing is essential towards gaining a full understanding of various physiological and pathological events. The in vivo level of hydrogen sulfide (H2S), the third endogenous gaseous transmitter, is closely related to its biological functions at different phases of the cell-division cycle. Here we report a facile strategy for H2S sensing in live cells at different phases of cell division by developing a fluorescent nanosensor with double-strand DNA (dsDNA)-stabilized silver nanoflakes (AgNF@dsDNA). The sensing principle is based on selective etching of AgNF@dsDNA by H2S, followed by conversion to Ag2S. AgNFs initially act as quenchers through surface energy transfer, and then its etching leads to fluorescence recovery of modified fluorophore and efficient fluorescence resonance energy transfer (FRET) between two fluorophores. The changes of FRET signal as the readout successfully enable semi-quantitative imaging of endogenous H2S alterations in live cells at G1, S, and G2, followed by the cycle...