Stable Domain Assembly of a Monomolecular DNA Quadruplex: Implications for DNA-Based Nanoswitches

Positional photocleavage control of DNA-based nanoswitches.

DNA-based switches are currently operated by manual solution-phase addition of 'set-strands'. We demonstrate another operation method-sterically inaccessible 'set-strands', released from a surface into solution by spatially controlled photocleavage. This technique will enable microarrays of set-strands to operate many DNA-based switches in self-contained computational and diagnostic devices.

Optomagnetic detection of DNA nanoswitches

Programmable pH-triggered DNA nanoswitches.

We have designed programmable DNA-based nanoswitches whose closing/opening can be triggered over specific different pH windows. These nanoswitches form an intramolecular triplex DNA structure through pH-sensitive parallel Hoogsteen interactions. We demonstrate that by simply changing the relative content of TAT/CGC triplets in the switches, we can rationally tune their pH dependence over more t...

Electronic control of DNA-based nanoswitches and nanodevices.

Here we demonstrate that we can rationally and finely control the functionality of different DNA-based nanodevices and nanoswitches using electronic inputs. To demonstrate the versatility of our approach we have used here three different model DNA-based nanoswitches triggered by heavy metals and specific DNA sequences and a copper-responsive DNAzyme. To achieve electronic-induced control of the...

Tuneable DNA-based asymmetric catalysis using a G-quadruplex supramolecular assembly.

Described is the first modular construction of a G-quadruplex chiral catalyst. The key objective was to use G-quadruplex structures to act as chiral ligands that would allow access to either enantiomer of the product of a Diels-Alder reaction.