Cavity hairpin ThT-light nucleic acid switches: the construction of label- and enzyme-free sensing and imaging platforms

Abstract Thioflavin T (ThT) is a classical fluorescent dye gaining prominence in current research regarding nucleic acid conformations (NACs). However, most NACs with the ability to excite ThT fluorescent are unique or form in demanding conditions, limiting the extensiveness and depth of ThT application in sensing and imaging. Therefore, this study proposed CGG-AAA mismatched cavity hairpin ThT-light nucleic acid switches (CHTLNAS) with excellent fluorescence excitation over 500-fold higher than spontaneous, 17∼20-fold higher than ssDNA and 2.5∼5-fold higher than complementary duplex. Based on the excellent fluorescence excitation, convenient conformation formation, good sequence programmability, and flexible allosteric ability (known as the Worm-crack pod mechanism mediated by the target), it achieved the label- and enzyme-free detection of tetracycline (TET) and berberine (BB) at the pM level within 10 min. Moreover, it was found enable to realize the sensitive tracking of intracellular carriers at the nM level of ThT entry concentration, and prolongated its cell nuclear-entry time of ThT over 8 h, overcoming the non-specific high background signal interference of ThT in the nuclear region, and expanding the diversified application of ThT in cell biology research. Therefore, CHTLNAS is a more universal, practical tool than G-quadruplex or other kinds of NACs for ThT development and utilization in sensing and imaging platforms.