Mechanisms of LncRNA Biogenesis As Revealed by Nascent Transcriptomics

Overview

Journal Nat Rev Mol Cell Biol

Specialties Cell Biology
Molecular Biology

Date 2022 Jan 26

PMID 35079163

Authors

Takayuki Nojima

Nick J Proudfoot

Affiliations

Soon will be listed here.

Abstract

Mammalian genomes express two principal gene categories through RNA polymerase II-mediated transcription: protein-coding transcription units and non-coding RNA transcription units. Non-coding RNAs are further divided into relatively abundant structural RNAs, such as small nuclear RNAs, and into a myriad of long non-coding RNAs (lncRNAs) of often low abundance and low stability. Although at least some lncRNA synthesis may reflect transcriptional 'noise', recent studies define unique functions for either specific lncRNAs or for the process of lncRNA synthesis. Notably, the transcription, processing and metabolism of lncRNAs are regulated differently from protein-coding genes. In this Review, we provide insight into the regulation of lncRNA transcription and processing gleaned from the application of recently devised nascent transcriptomics technology. We first compare and contrast different methodologies for studying nascent transcription. We then discuss the molecular mechanisms regulating lncRNA transcription, especially transcription initiation and termination, which emphasize fundamental differences in their expression as compared with protein-coding genes. When perturbed, lncRNA misregulation leads to genomic stress such as transcription-replication conflict and R-loop-mediated DNA damage. We discuss many unresolved but important questions about the synthesis and potential functions of lncRNAs.

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