Generation of Small Molecule-binding RNA Arrays and Their Application to Fluorogen-binding RNA Aptamers

Overview

Journal Methods

Specialty Biochemistry

Date 2019 May 6

PMID 31055072

Citations 2

Authors

Charlotte A Henderson

Callum A Rail

Louise E Butt

Helen A Vincent

Anastasia J Callaghan

Affiliations

Soon will be listed here.

Abstract

The discovery and engineering of more and more functions of RNA has highlighted the utility of RNA-targeting small molecules. Recently, several fluorogen-binding RNA aptamers have been developed that have been applied to live cell imaging of RNA and metabolites as RNA tags or biosensors, respectively. Although the design and application of these fluorogen-binding RNA aptamer-based devices is straightforward in theory, in practice, careful optimisation is required. For this reason, high throughput in vitro screening techniques, capable of quantifying fluorogen-RNA aptamer interactions, would be beneficial. We recently developed a method for generating functional-RNA arrays and demonstrated that they could be used to detect fluorogen-RNA aptamer interactions. Specifically, we were able to visualise the interaction between malachite green and the malachite green-binding aptamer. Here we expand this study to demonstrate that functional-RNA arrays can be used to quantify fluorogen-aptamer interactions. As proof-of-concept, we provide detailed protocols for the production of malachite green-binding RNA aptamer and DFHBI-binding Spinach RNA aptamer arrays. Furthermore, we discuss the potential utility of the technology to fluorogen-binding RNA aptamers, including application as a molecular biosensor platform. We anticipate that functional-RNA array technology will be beneficial for a wide variety of biological disciplines.

Citing Articles

Generation of Functional-RNA Arrays by In Vitro Transcription and In Situ RNA Capture for the Detection of RNA-RNA Interactions.

Vincent H, Henderson C, Lopes Cardoso D, Callaghan A Methods Mol Biol. 2023; 2633:163-184.

PMID: 36853464 DOI: 10.1007/978-1-0716-3004-4_13.

How to copy and paste DNA microarrays.

Kramer S, Wohrle J, Meyer P, Urban G, Roth G Sci Rep. 2019; 9(1):13940.

PMID: 31558745 PMC: 6763488. DOI: 10.1038/s41598-019-50371-1.

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