Semi-quantitative detection of pseudouridine modifications and type I/II hypermodifications in human mRNAs using direct long-read sequencing.
Sepideh TavakoliMohammad NabizadehAmr MakhamrehHoward B GamperCaroline A McCormickNeda K RezapourYa-Ming HouMeni WanunuSara H RouhanifardPublished in: Nature communications (2023)
Here, we develop and apply a semi-quantitative method for the high-confidence identification of pseudouridylated sites on mammalian mRNAs via direct long-read nanopore sequencing. A comparative analysis of a modification-free transcriptome reveals that the depth of coverage and specific k-mer sequences are critical parameters for accurate basecalling. By adjusting these parameters for high-confidence U-to-C basecalling errors, we identify many known sites of pseudouridylation and uncover previously unreported uridine-modified sites, many of which fall in k-mers that are known targets of pseudouridine synthases. Identified sites are validated using 1000-mer synthetic RNA controls bearing a single pseudouridine in the center position, demonstrating systematic under-calling using our approach. We identify mRNAs with up to 7 unique modification sites. Our workflow allows direct detection of low-, medium-, and high-occupancy pseudouridine modifications on native RNA molecules from nanopore sequencing data and multiple modifications on the same strand.
Keyphrases
- single cell
- single molecule
- high resolution
- endothelial cells
- electronic health record
- gene expression
- emergency department
- rna seq
- loop mediated isothermal amplification
- healthcare
- big data
- optical coherence tomography
- coronavirus disease
- artificial intelligence
- genome wide analysis
- genetic diversity
- quantum dots
- affordable care act