posted on 2016-02-20, 13:14authored byBingling Li, Yu Jiang, Xi Chen, Andrew D. Ellington
Catalyzed hairpin assembly (CHA) is a robust enzyme-free
signal-amplification
reaction that has a wide range of potential applications, especially
in biosensing. Although most studies of the analytical applications
of CHA have focused on the measurement of concentrations of biomolecules,
we show here that CHA can also be used to probe the spatial organization
of biomolecules such as single-stranded DNA. The basis of such detection
is the fact that a DNA structure that brings a toehold and a branch-migration
domain into close proximity can catalyze the CHA reaction. We quantitatively
studied this phenomenon and applied it to the detection of domain
reorganization that occurs during DNA self-assembly processes such
as the hybridization chain reaction (HCR). We also show that CHA circuits
can be designed to detect certain types of hybridization defects.
This principle allowed us to develop a “signal on” assay
that can simultaneously respond to multiple types of mutations in
a DNA strand in one simple reaction, which is of great interest in
genotyping and molecular diagnostics. These findings highlight the
potential impacts of DNA circuitry on DNA nanotechnology and provide
new tools for further development of these fields.