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Nanopore Dwell Time Analysis Permits Sequencing and Conformational Assignment of Pseudouridine in SARS-CoV-2

Aaron M. Fleming, Nicole J Mathewson, Shereen A. Howpay Manage, Cynthia J. Burrows

2021ACS Central Science85 citationsDOIOpen Access PDF

Abstract

Direct RNA sequencing for the epitranscriptomic modification pseudouridine (Ψ), an isomer of uridine (U), was conducted with a protein nanopore sensor using a helicase brake to slowly feed the RNA into the sensor. Synthetic RNAs with 100% Ψ or U in 20 different known human sequence contexts identified differences during sequencing in the base-calling, ionic current, and dwell time in the nanopore sensor; however, the signals were found to have a dependency on the context that would result in biases when sequencing unknown samples. A solution to the challenge was the identification that the passage of Ψ through the helicase brake produced a long-range dwell time impact with less context bias that was used for modification identification. The data analysis approach was employed to analyze publicly available direct RNA sequencing data for SARS-CoV-2 RNA taken from cell culture to locate five conserved Ψ sites in the genome. Two sites were found to be substrates for pseudouridine synthase 1 and 7 in an in vitro assay, providing validation of the analysis. Utilization of the helicase as an additional sensor in direct RNA nanopore sequencing provides greater confidence in calling RNA modifications.

Topics & Concepts

RNANanopore sequencingContext (archaeology)Computational biologyNanoporeBiologyPseudouridineHelicaseGeneticsGeneDNA sequencingTransfer RNANanotechnologyMaterials sciencePaleontologyRNA modifications and cancerRNA and protein synthesis mechanismsRNA Research and Splicing