The detection, function, and therapeutic potential of RNA 2'-O-methylation
The RNA modification 2'-O-methylation (Nm) is an essential RNA modification found across nearly all types of RNAs. This review compares Nm detection methods, and examines its biological roles in health and disease. Researchers have recently used Oxford Nanopore direct RNA sequencing and the NanoNm machine learning tool to map thousands of Nm sites at single-base resolution. They found that Nm has regulatory and structural roles, with implications for cancer, neurodegeneration, and viral immune evasion — highlighting its potential as a biomarker and therapeutic target in the future.
Key points:
Oxford Nanopore technology enabled amplification-free, full-length RNA sequencing and quantitative Nm detection with single-nucleotide precision, overcoming the major limitations of short-read and chemical-based methods
NanoNm enables de novo, single-base resolution of Nm from Oxford Nanopore direct RNA sequencing data
Thousands of Nm sites have been identified in human mRNA and rRNA
Stoichiometric analysis suggests Nm plays a regulatory role in mRNA and a structural role in rRNA
Nm is enriched near stop codons and linked to mRNA stability, shortened 3'-UTRs, and increased gene expression
Fibrillarin overexpression increases Nm on cancer-related transcripts, linking Nm to disease-relevant gene regulation
Studying Nm could reveal novel diagnostic markers and therapeutic strategies for a wide range of diseases in the future
'The unprecedented development of [Oxford] Nanopore sequencing... offers real-time, single-molecule sequencing capabilities that addresses the limitations of previous methods. This advancement holds immense potential for achieving absolute quantitation of Nm levels'
Wu and Li et al. 2025
