A spring-loaded and leakage-tolerant synthetic gene switch for in-vitro detection of DNA and RNA

Nucleic acid tests (NATs) are essential for biomedical diagnostics. Traditional NATs, often complex and expensive, have prompted the exploration of Toehold-Mediated Strand Displacement (TMSD) circuits as an economical alternative. However, the wide application of TMSD-based reactions is limited by ‘leakage’—the spurious activation of the reaction leading to high background signals and false positives. Here we introduce a new TMSD cascade that recognizes a custom nucleic acid input and generates an amplified output. The system is based on a pair of thermodynamically spring-loaded DNA modules. The binding of a predefined nucleic acid target triggers an intermolecular reaction that activates a T7 promoter, leading to the perpetual transcription of a fluorescent aptamer that can be detected by a smartphone camera. The system is designed to permit the selective depletion of leakage byproducts to achieve high sensitivity and zero-background signal in the absence of the correct trigger. Using Zika virus (ZIKV)- and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)-derived nucleic acid sequences, we show that the assay generates a reliable target-specific readout. Native RNA can be directly detected under isothermal conditions, without requiring reverse transcription, with a sensitivity as low as 200 attomole. The modularity of the assay allows easy re-programming for the detection of other targets by exchanging a single sequence domain. This work provides a low-complexity and high-fidelity synthetic biology tool for point-of-care diagnostics and for the construction of more complex biomolecular computations. ### Competing Interest Statement The authors have declared no competing interest.