Tuning phenolic hemicyanines for ratiometric DNA sensing and live cell nuclear bioimaging applications

Abstract

Activatable fluorescent probes with turn-on emission in response to a biological target can reduce the background signal and improve the detection limit needed for biosensor and bioimaging resolution. Turn-on probes with dual emission (ratiometric probes) have further advantages, as they have self-calibration ability for more reliable detection. Herein, we demonstrate the tunability of the phenolic hemicyanine (HC) scaffold for both DNA biosensing and bioimaging applications using the quinine-binding DNA aptamer (MN4) as a host-guest biosensor platform and live ovarian cancer cells for nuclear imaging. The DNA aptamer MN4 contains a three-way junction (3WJ) consisting of a hydrophobic branch point connecting three double-stranded stems. Phenolic HCs bearing electron-withdrawing halogen substituents (FPhOBtz and Cl2PhOBTz) bind to the 3WJ of MN4 as the phenolate with strong turn-on emission. Subsequent displacement of the phenolate by the quinine target causes a turn-off emission response. In contrast, the parent phenolic HC (PhOBtz) and those bearing electron-donating groups (Me2PhOBtz and (MeO)2PhOBtz) exhibit dual (phenol and phenolate) fluorescence upon MN4 binding. Phenol excitation generates phenolate emission by an excited-state proton transfer (ESPT) process with DNA components serving as the proton acceptor. Quinine displacement of PhOBtz from the 3WJ of MN4 affords a turn-on ratiometric response with preferential light-up of phenol emission. The ability of the phenolic HCs to serve as cellular nuclear stains further highlights the tunability of the phenolic HC probes with the Cl2PhOBtz analog displaying superior staining ability. The simplicity and tunability of phenolic HCs make them attractive fluorescent probes for DNA sensing and bioimaging applications.