Ultrasensitive detection of DNA based on target-triggered hairpin assembly and exonuclease-assisted recycling amplification

Abstract

An ultrasensitive electrochemical detection of target DNA was developed based on target-triggered hairpin assembly and exonuclease III (Exo III)-assisted recycling quadratic amplification strategy. The detection employed a gold nanoparticles (AuNPs) modified Au electrode and two specially designed hairpin probes P1 and P2. P1 probe contained G-quadruplex-forming sequence and target DNA recognition region, and was immobilized on the electrode. P2 probe was used as a secondary complementary sequence which can displace target DNA and hybridize with P1 probe. In the absence of target DNA, these hairpin structures of P1 and P2 can coexist. While in the presence of target DNA, it can trigger the self-assembly process of P1 and P2 and initiate the Exo III-assisted two recycling process, resulting in the formation of G-quadruplex structure on electrode surface. Finally, with the addition of hemin, numerous G-quadruplex-hemin complexes formed on the electrode surface and gave a pronounced electrochemical response in differential pulse voltammogram (DPV). Taking K-ras proto oncogene as an example, the proposed DNA biosensor exhibited a wide detection range from 10fM to 20nM, and an extremely low detection limit of 2.86fM. Moreover, it can clearly discriminate one-base difference in DNA sequence, thus can identify the mutation of the target gene. The proposed DNA biosensor has potential applications in the fields of clinic diagnosis, biomedicine, food and environment microbial monitoring.