Aptamer based electrochemical adenosine triphosphate assay based on a target-induced dendritic DNA nanoassembly

Abstract

The authors describe an electrochemical strategy for highly sensitive determination of ATP that involves (a) aptamer-based target recognition, (b) enzyme-free dendritic DNA nanoassembly amplification with multiplex binding of the biotin-strepavidin system, and (c) enzyme-amplified differential pulse voltammetric readout. In the presence of ATP, binding of ATP to the aptamer releases trigger DNA from the double-stranded complex between ATP aptamer and trigger DNA. The single-stranded thiolated capture probe, chemisorbed on the gold electrode surface, captures the released trigger DNA via hybridization. The toehold of the trigger DNA is recombined with one end of the first substrate DNA (1) which is on its other end biotinylated and blocked, with loops, by a counterstrand. The latter is removed by a complementary single-stranded helper (1) exposing two toeholds and two identical complimentary sequences for a second biotinylated substrate DNA (2). The latter, which is double-stranded except for the toehold, binds to one of these two sites. It is then stripped from its counter strand by another single-stranded helper DNA 2, exposing a toehold to bind another substrate DNA 1. On this substrate, another cycle with dentrimeric bransching can start. Substrate 1 with its two binding sites for substrate 2 initiates the assembly of dendritic DNA on the surface of the gold electrode, which finally possesses numerous biotins at the terminal ends of both of the associated substrate DNAs. Subsequent multiplex binding of streptavidinylated alkaline phosphatase and enzyme-amplified electrochemical readout leads to a highly sensitive electrochemical ATP aptasensor. If operated in the DPV mode, the current as measured at a typical working potential of 0.25 V (vs. Ag/AgCl) increases linearly over the 10 nM to 10 μM logarithmic ATP concentration range, and the detection limit is 5.8 nM (at an S/N ratio of 3). The assay is highly specific and reproducible. It was successfully applied to the detection of ATP in spiked human serum samples.