Litcius/Paper detail

A Photoresponsive Intramolecular Triplex Motif That Enables Rapid and Reversible Control of Aptamer Binding Activity

Tuan Trinh, Ian A. P. Thompson, Finley Clark, Jacob M. Remington, Michael Eisenstein, Jianing Li, H. Tom Soh

2022ACS Nano32 citationsDOI

Abstract

DNA switches that can change conformation in response to certain wavelengths of light could enable rapid and noninvasive control of chemical processes for a wide range of applications. However, most current photoresponsive DNA switches are limited by either irreversible switching or reversible switching with impractically slow kinetics. Here, we report the design of an intramolecular triplex photoswitch (TPS) design based on single-stranded DNA that undergoes rapid and reversible photoswitching between folded and unfolded states through isomerization of internal azobenzene modifications. After optimizing the performance of our photoswitch design, we used molecular dynamics simulations to reveal how individual azobenzenes contribute to the stabilization or destabilization of the triplex depending on their photoisomerization state. By coupling our TPS to an existing aptamer, we can reversibly modulate its binding affinity with less than 15 s of UV light exposure. We further demonstrate reproducible shifting in affinity over multiple cycles of UV and blue light irradiation without substantial photobleaching.

Topics & Concepts

PhotoswitchPhotoisomerizationAzobenzeneAptamerIntramolecular forceDNAChemistryMolecular switchIsomerizationBiophysicsMaterials sciencePhotochemistryMoleculeStereochemistryBiochemistryCatalysisGeneticsBiologyOrganic chemistryAdvanced biosensing and bioanalysis techniquesDNA and Nucleic Acid ChemistryPhotochromic and Fluorescence Chemistry