Publication

Harnessing Nature's Molecular Recognition Capabilities to Map and Study RNA Modifications

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Last modified
  • 06/25/2025
Type of Material
Authors
    Ansley S. Felix, Emory UniversityAlexandria L. Quillin, Emory UniversityShikufa Mousavi, Emory UniversityJennifer Heemstra, Emory University
Language
  • English
Date
  • 2022-08-16
Publisher
  • ACS Publications
Publication Version
Copyright Statement
  • © 2022 American Chemical Society
Final Published Version (URL)
Title of Journal or Parent Work
Volume
  • 55
Issue
  • 16
Start Page
  • 2271
End Page
  • 2279
Grant/Funding Information
  • This work was supported by the National Institutes of Health (R35 GM144075 to J.M.H.).
Abstract
  • ConspectusRNA editing or "epitranscriptomic modification"refers to the processing of RNA that occurs after transcription to alter the sequence or structure of the nucleic acid. These chemical alterations can be found on either the ribose sugar or the nucleobase, and although many are "silent"and do not change the Watson-Crick-Franklin code of the RNA, others result in recoding events. More than 170 RNA modifications have been identified so far, each having a specific biological purpose. Additionally, dysregulated RNA editing has been linked to several types of diseases and disorders. As new modifications are discovered and our understanding of their functional impact grows, so does the need for selective methods of identifying and mapping editing sites in the transcriptome.The most common methods for studying RNA modifications rely on antibodies as affinity reagents; however, antibodies can be difficult to generate and often have undesirable off-target binding. More recently, selective chemical labeling has advanced the field by offering techniques that can be used for the detection, enrichment, and quantification of RNA modifications. In our method using acrylamide for inosine labeling, we demonstrated the versatility with which this approach enables pull-down or downstream functionalization with other tags or affinity handles. Although this method did enable the quantitative analysis of A-to-I editing levels, we found that selectivity posed a significant limitation, likely because of the similar reactivity profiles of inosine and pseudouridine or other nucleobases.Seeking to overcome the inherent limitations of antibodies and chemical labeling methods, a more recent approach to studying the epitranscriptome is through the repurposing of proteins and enzymes that recognize modified RNA. Our laboratory has used Endonuclease V, a repair enzyme that cleaves inosine-containing RNAs, and reprogrammed it to instead bind inosine. We first harnessed EndoV to develop a preparative technique for RNA sequencing that we termed EndoVIPER-seq. This method uses EndoV to enrich inosine-edited RNAs, providing better coverage in RNA sequencing and leading to the discovery of previously undetected A-to-I editing sites. We also leveraged EndoV to create a plate-based immunoassay (EndoVLISA) to quantify inosine in cellular RNA. This approach can detect differential A-to-I editing levels across tissue types or disease states while being independent of RNA sequencing, making it cost-effective and high-throughput. By harnessing the molecular recognition capabilities of this enzyme, we show that EndoV can be repurposed as an "anti-inosine antibody"to develop new methods of detecting and enriching inosine from cellular RNA.Nature has evolved a plethora of proteins and enzymes that selectively recognize and act on RNA modifications, and exploiting the affinity of these biomolecules offers a promising new direction for the field of epitranscriptomics.
Author Notes
  • Jennifer M. Heemstra – Department of Chemistry, Washington University in St. Louis, St. Louis, MO 63130 USA; heemstra@wustl.edu
Keywords
Research Categories
  • Biology, Molecular
  • Biology, Genetics

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