DNA‐Mediated Proximity‐Based Assembly Circuit for Actuation of Biochemical Reactions

Smart nanodevices that integrate molecular recognition and signal production hold great promise for the point‐of‐care (POC) diagnostic applications. Herein, the development of a DNA‐mediated proximity assembly of biochemical reactions, which was capable of sensing various bio‐targets and reporting easy‐to‐read signals is reported. The circuit was composed of a DNA hairpin‐locked catalytic cofactor with inhibited activity. Specific molecular inputs can trigger a conformational switch of the DNA locks through the mechanisms of toehold displacement and aptamer switching, exposing an active cofactor. The subsequent assembly of an enzyme/cofactor pair actuated a reaction to produce colorimetric or fluorescence signals for detecting target molecules. The developed system could be potentially applied to smart biosensing in molecular diagnostics and POC tests. DNA directed detection: A robust, smart DNA nanodevice capable of sensing various bio‐targets and reporting an easy‐to‐read signal was designed. A DNA logic‐gated structure was used to mediate the proximity‐based assembly of an enzyme/cofactor system that can detect target molecules by catalyzing the production of colorimetric or fluorescence signals.