Turn-on RNA Mango Beacons for Trans-Acting Fluorogenic Nucleic Acid Detection
- Amir Abdolahzadeh1,
- Quiana R Ang1,
- Jana R Caine2,
- Shanker Shyam S Panchapakesan3,
- Shinta Thio1,
- Razvan Cojocaru1 and
- Peter Unrau1,4
- 1 Simon Fraser University, Department of Molecular Biology and Biochemistry;
- 2 The University of British Columbia, Department of Chemistry;
- 3 SASTRA University, School of Chemical and Biotechnology
- ↵* Corresponding author; email: punrau{at}sfu.ca
Abstract
The Mango I and II RNA aptamers have been widely used in vivo and in vitro as genetically-encodable fluorogenic markers that undergo large increases in fluorescence upon binding to their ligand, TO1-biotin. However, while studying nucleic acids sequences, it is often desirable to have trans-acting probes that induce fluorescence upon binding to a target sequence. Here, we rationally design three types of light-up RNA Mango Beacons based on a minimized Mango core, that induce fluorescence upon binding to a target RNA strand. Our first design is bi-molecular in nature and uses a DNA inhibition strand to prevent folding of the Mango aptamer core until binding to a target RNA. Our second design is unimolecular in nature, and features hybridization arms flanking the core that inhibit G-quadruplex folding until refolding is triggered by binding to a target RNA strand. Our third design builds upon this structure, and incorporates a self-inhibiting domain into one of the flanking arms that deliberately binds to, and precludes folding of, the aptamer core until a target is bound. This design separates G-quadruplex folding inhibition and RNA target hybridization into separate modules enabling a more universal unimolecular beacon design. All three Mango Beacons feature high contrasts and low costs, when compared to conventional molecular beacons, with excellent potential for in vitro and in vivo applications.
Keywords
- G-quadruplex folding regulation
- RNA Mango aptamer
- fluorescent reporter
- molecular beacon
- nucleic acid reporting
- Received September 11, 2023.
- Accepted January 3, 2024.
- Published by Cold Spring Harbor Laboratory Press for the RNA Society
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