A Simple Colorimetric System for Detecting Target Antigens by a Three-Stage Signal Transformation–Amplification Strategy

Inexpensive, straightforward, and rapid medical diagnostics are becoming increasingly important for disease identification in time- and resource-limited settings. Previous attempts to link oligonucleotide-based aptamers and hammerhead ribozymes to form ligand-induced ribozymes have been successful in identifying a variety of small molecule and protein targets. Isothermal exponential amplification reactions (EXPAR) amplify minute amounts of nucleic acid templates without requiring special instrumentation. We introduce a colorimetric assay that we engineered using an aptamer, hammerhead ribozyme, EXPAR, and peroxidase activity in conjunction with a 3,3′,5,5′-tetramethylbenzidine (TMB) substrate. This is a modular signal enhancer system that can be easily modified to detect virtually any chosen analyte target within 5–10 min with minimal technical requirements. Ligand–aptamer binding causes the ribozyme to change conformation and self-cleave. The cleaved ribozyme triggers exponential amplification of a reporter sequence during EXPAR. The amplification products fold into single-stranded DNA guanine quadruplexes that exhibit peroxidase-like activity and can oxidize a colorless TMB substrate into a colored reaction product for visual detection. As a proof of concept, we examined the bronchodilator theophylline versus its chemical analogue, caffeine. We demonstrate linear changes in absorption readout across a wide range of target concentrations (0.5–1000 μM) and the ability to visually detect theophylline at 0.5 μM with an approximately 35-fold increased specificity versus that of caffeine. This three-stage detection system is a versatile platform that has the potential to improve the rapid identification of target analytes.