Triggered Polycatenated DNA Scaffolds for DNA Sensors and Aptasensors by a Combination of Rolling Circle Amplification and DNAzyme Amplification

The concept of triggered polycatenated DNA scaffolds has been elegantly introduced into ultrasensitive biosensing applications by a combination of rolling circle amplification (RCA) and DNAzyme amplification. As compared to traditional methods in which one target could only initiate the formation of one circular template for RCA reaction, in the present study two species of linear single-stranded DNA (ssDNA) monomers are self-assembled into mechanically interlocked polycatenated nanostructures on capture probe-tagged magnetic nanoparticles (MNPs) only upon the introduction of one base mutant DNA sequence as initiator for single-nucleotide polymorphisms (SNPs) analysis. The resultant topologically polycatenated DNA ladder is further available for RCA process by using the serially ligated circular DNA as template for the synthesis of hemin/G-quadruplex HRP-mimicking DNAzyme chains, which act as biocatalytic labels for the luminol-H(2)O(2) chemiluminescence (CL) system. Notably, the problem of high background induced by excess hemin itself is circumvented by immobilizing the biotinylated RCA products on streptavidin-modified MNPs via biotin-streptavidin interaction. Similarly, a universal strategy is contrived by substitutedly employing aptamer as initiator for the construction of polycatenated DNA scaffolds to accomplish ultrasensitive detection of proteins based on structure-switching of aptamer upon target binding, which is demonstrated by using thrombin as a model analyte in this study. Overall, with two successive amplification steps and one magnetic separation procedure, this flexible biosensing system exhibits not only high sensitivity and specificity with the detection limits of SNPs and thrombin as low as 71 aM and 6.6 pM, respectively, but also excellent performance in real human serum assay with no PCR preamplification for SNPs assay. Given the unique and attractive characteristics, this study illustrates the potential of DNA nanotechnology in bioanalytical applications for both fundamental and practical research.