DNA-templated silver nanoclusters (AgNC@DNA) are a novel type of nanomaterial with advantageous optical properties. Only a few atoms in size, the fluorescence of nanoclusters can be tuned using DNA overhangs. In this study, we explored the properties of AgNCs manufactured on a short single-stranded (dC)12 when adjacent G-rich sequences (dGN , with N = 3-15) were added. The 'red' emission of AgNC@dC12 with λMAX = 660 nm dramatically changed upon the addition of a G-rich overhang with NG = 15. The pattern of the emission-excitation matrix (EEM) suggested the emergence of two new emissive states at λMAX = 575 nm and λMAX = 710 nm. The appearance of these peaks provides an effective way to design biosensors capable of detecting specific nucleic acid sequences with low fluorescence backgrounds. We used this property to construct an NA-based switch that brings AgNC and the G overhang near one another, turning 'ON' the new fluorescence peaks only when a specific miRNA sequence is present. Next, we tested this detection switch on miR-371, which is overexpressed in prostate cancer. The results presented provide evidence that this novel fluorescent switch is both sensitive and specific with a limit of detection close to 22 picomoles of the target miR-371 molecule.
Keywords: G-base effect; cytosine-rich sequences; fluorescence; miRNA detection; silver nanoclusters.
© 2023 The Authors. Luminescence published by John Wiley & Sons Ltd.