MicroRNAs (miRNAs) are currently considered as potential biomarkers for various human diseases. In the present study, miRNA-triggered real-time fluorescent isothermal reaction with exponential amplification (ReFIRE) with or without Thermus aquaticus MutS (Taq MutS) was developed to analyze miRNAs using DNA polymerase, a nicking endonuclease, and fluorescently labeled primers. In the absence of Taq MutS, the ReFIRE system permitted the detection of 100 ymol of targeted miRNA in 80 min. However, this system enabled limited differentiation between homologous miRNA family members. Upon addition of Taq MutS to the ReFIRE system, non-specific amplification generated from the mishybridization between primers and primer dimers or primers and the template duplex was eliminated. The addition of Taq MutS enabled the ultrasensitive detection of as little as 10 ymol of targeted miRNAs in 50 min, which corresponds to less than 10 copies of miRNAs in a total volume of 20 μl. Additionally, the assay exhibited a dynamic range of up to 12 orders of magnitude. The ReFIRE system also showed high specificity, enabling differentiation between homologous miRNA family members exhibiting only single-base differences. The sensitivity, specificity, and dynamic range associated with this system were greater than most currently available miRNA isothermal amplification assays. Moreover, when target-specific primers were labeled with different fluorescent reporters, multiplex analysis was easily performed in a single tube, permitting accurate normalization of miRNA expression. This simple, fast, ultrasensitive, highly specific, and easy-to-multiplex method could significantly contribute to research investigations pertaining to the biological roles of miRNA, as well as clinical diagnosis of various diseases that involve miRNA disruptions. Graphical Abstract The principle of ReFIRE system.
Keywords: Isothermal exponential amplification; MicroRNAs; Nicking endonuclease; Strand displacement.