Detection of differential RNA modifications from direct RNA sequencing of human cell lines

Pratanwanich, Naruemon; Yao, Fei; Chen, Ying; Koh, Casslynn W Q; Hendra, Christopher; Poon, Polly; Goh, Yeek Teck; Yap, Phoebe M. L.; Yuan, Choi Jing; Chng, Wee Joo; Ng, Sarah; Thiéry, Alexandre H.; Göke, Jonathan

doi:10.1101/2020.06.18.160010

Cited by 16 publications

(20 citation statements)

References 35 publications

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“…As expected, m6A sites identified using direct RNA-Seq data show an enrichment at the 3' end of transcripts and resemble the expected DRACH motif (Figure 8b, Supplementary Figure 5a). Candidate m6A sites also show a shift in the current signal that corresponds to the expected deviation due to m6A modifications, further suggesting that sites identified with direct RNA-Seq data are indeed modified by m6A (Figure 8c, Supplementary Figure 5b) 33 . Globally, we observe that m6A sites show cell type-specificity, partially due to cell type-specific expression of transcripts (Figure 8d, e, Supplementary Figure 5c).…”

Section: (9) the Landscape Of M6a Rna Modifications In The Sg-nex Cell Linesmentioning

confidence: 78%

A systematic benchmark of Nanopore long read RNA sequencing for transcript level analysis in human cell lines

Chen

Davidson

et al. 2021

Preprint

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The human genome contains more than 200,000 gene isoforms. However, different isoforms can be highly similar, and with an average length of 1.5kb remain difficult to study with short read sequencing. To systematically evaluate the ability to study the transcriptome at a resolution of individual isoforms we profiled 5 human cell lines with short read cDNA sequencing and Nanopore long read direct RNA, amplification-free direct cDNA, PCR-cDNA sequencing. The long read protocols showed a high level of consistency, with amplification-free RNA and cDNA sequencing being most similar. While short and long reads generated comparable gene expression estimates, they differed substantially for individual isoforms. We find that increased read length improves read-to-transcript assignment, identifies interactions between alternative promoters and splicing, enables the discovery of novel transcripts from repetitive regions, facilitates the quantification of full-length fusion isoforms and enables the simultaneous profiling of m6A RNA modifications when RNA is sequenced directly. Our study demonstrates the advantage of long read RNA sequencing and provides a comprehensive resource that will enable the development and benchmarking of computational methods for profiling complex transcriptional events at isoform-level resolution.

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Section: (9) the Landscape Of M6a Rna Modifications In The Sg-nex Cell Linesmentioning

confidence: 78%

A systematic benchmark of Nanopore long read RNA sequencing for transcript level analysis in human cell lines

Chen

Davidson

et al. 2021

Preprint

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“…However, the detection of different DNA nucleotides within the reads: A, G, C, T, m 6 A and m 5 C. However, this is not yet the reality for direct RNA sequencing, partly due to the higher noise-to-signal ratio of RNA nanopore reads. Consequently, solutions to identify RNA modifications in direct RNA sequencing data have so far relied on the use of post-processing software [28][29][30]32,33,87 .…”

Section: Discussionmentioning

confidence: 99%

“…Algorithms to detect RNA modifications have been made available in the last few months (Leger et al, 2019;Liu et al, 2019;Parker et al, 2020), many of which rely on the use of systematic base-calling 'errors' caused by the presence of RNA modifications. However, to date the vast majority of efforts have been devoted to the detection of m 6 A modifications (Liu et al, 2019;Parker et al, 2020;Pratanwanich et al, 2020;Price et al, 2019). Thus, it is largely unknown whether other modifications of RNA bases may be distinguishable from their unmodified counterparts using this technology.…”

Section: Introductionmentioning

confidence: 99%

Quantitative profiling of native RNA modifications and their dynamics using nanopore sequencing

Begik

Lucas

Pryszcz

et al. 2020

Preprint

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SUMMARYA broad diversity of modifications decorate RNA molecules. Originally conceived as static components, evidence is accumulating that some RNA modifications may be dynamic, contributing to cellular responses to external signals and environmental circumstances. A major difficulty in studying these modifications, however, is the need of tailored protocols to map each modification individually. Here, we present a new approach that uses direct RNA nanopore sequencing to identify diverse RNA modification types present in native RNA molecules, using rRNA as the exemplar, and show that each RNA modification type results in distinct and characteristic base-calling ‘error’ signatures. We demonstrate the value of these signatures for de novo prediction of pseudouridine (Y) modifications transcriptome-wide, confirming known Y modifications in rRNAs, snRNAs and mRNAs, and uncovering a novel Pus4-dependent Y modification in yeast mitochondrial rRNA. Using a machine learning classifier, we show that the stoichiometry of modified sites can be quantified by identifying current intensity alterations in individual RNA reads. Finally, we explore the dynamics of pseudouridylation across a battery of environmental stresses, revealing novel heat-sensitive Y-modified sites in both snRNAs and snoRNAs. Altogether, our work demonstrates that Y RNA modifications can be predicted de novo and in a quantitative manner using native RNA nanopore sequencing.

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“…To address these limitations, direct RNA sequencing platform provided by ONT has emerged as an ideal alternative technology, which has the potential to detect sites of modification in native RNA molecule ( Garalde et al, 2018 ). Direct RNA nanopore sequencing has been used to analyze m6A in yeast ( Garalde et al, 2018 ; Liu H. et al, 2019 ), Arabidopsis ( Parker et al, 2020 ), RNA virus genomes ( Kim et al, 2020 ), and human cells ( Leger et al, 2019 ; Workman et al, 2019 ; Lorenz et al, 2020 ; Pratanwanich et al, 2020 ; Jenjaroenpun et al, 2021 ). For example, Workman et al (2019) conducted direct RNA-seq analysis of RNA from a human cell line GM12878, in vitro transcribed RNA from cDNA from the same cell line, and synthetic RNA.…”

Section: Detection Of Rna Modification By Nanopore Sequencingmentioning

confidence: 99%

Cancer Biomarkers Discovery of Methylation Modification With Direct High-Throughput Nanopore Sequencing

Zhang

Xie

et al. 2021

Front. Genet.

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Cancer is a complex disease, driven by a combination of genetic and epigenetic alterations. DNA and RNA methylation modifications are the most common epigenetic events that play critical roles in cancer development and progression. Bisulfite converted sequencing is a widely used technique to detect base modifications in DNA methylation, but its main drawbacks lie in DNA degradation, lack of specificity, or short reads with low sequence diversity. The nanopore sequencing technology can directly detect base modifications in native DNA as well as RNA without harsh chemical treatment, compared to bisulfite sequencing. Furthermore, CRISPR/Cas9-targeted enrichment nanopore sequencing techniques are straightforward and cost-effective when targeting genomic regions are of interest. In this review, we mainly focus on DNA and RNA methylation modification detection in cancer with the current nanopore sequencing approaches. We also present the respective strengths, weaknesses of nanopore sequencing techniques, and their future translational applications in identification of epigenetic biomarkers for cancer detection and prognosis.

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Detection of differential RNA modifications from direct RNA sequencing of human cell lines

Cited by 16 publications

References 35 publications

A systematic benchmark of Nanopore long read RNA sequencing for transcript level analysis in human cell lines

A systematic benchmark of Nanopore long read RNA sequencing for transcript level analysis in human cell lines

Quantitative profiling of native RNA modifications and their dynamics using nanopore sequencing

Cancer Biomarkers Discovery of Methylation Modification With Direct High-Throughput Nanopore Sequencing

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