A DNA-based Two-way Thermometer to Report High And Low Temperatures

Abstract Precise description of temperature at the microscale level is essential in many biological applications. In this study, we prepared a DNA-based thermometer that reports low and high temperatures by providing two distinct optical signals. The system is a molecular beacon that carries a loop and a stem, whose conformation is subject to change from a hairpin to a random coil when the temperature changes from low to high. A fluorophore, Cy5, and a quencher, BHQ3, are terminally labeled at the stem ends. Moreover, perylene is included in the middle of the 3′ end stem. The signaling state of Cy5 relies on the relative distance to BHQ3. However, the perylene emission is regulated by its microenvironment (i.e., the oligonucleotide or duplex state). With a temperature variation, the designed thermometer undergoes a change in conformation that leads to two signal patterns with Cy5/off and perylene/on at low temperature and Cy5/on and perylene/off at high temperature. The reversibility and biocompatibility of the thermometer design were examined for potential applications in biological systems.