Transcriptome-scale RNA-targeting CRISPR Screens Reveal Essential LncRNAs in Human Cells

Overview

Journal Cell

Publisher Cell Press

Specialty Cell Biology

Date 2024 Nov 12

PMID 39532094

Authors

Wen-Wei Liang

Simon Muller

Sydney K Hart

Hans-Hermann Wessels

Alejandro Mendez-Mancilla

Akash Sookdeo

Olivia Choi

Christina M Caragine

Alba Corman

Lu Lu

Olena Kolumba

Breanna Williams

Neville E Sanjana

Affiliations

Soon will be listed here.

Abstract

Mammalian genomes host a diverse array of RNA that includes protein-coding and noncoding transcripts. However, the functional roles of most long noncoding RNAs (lncRNAs) remain elusive. Using RNA-targeting CRISPR-Cas13 screens, we probed how the loss of ∼6,200 lncRNAs impacts cell fitness across five human cell lines and identified 778 lncRNAs with context-specific or broad essentiality. We confirm their essentiality with individual perturbations and find that the majority of essential lncRNAs operate independently of their nearest protein-coding genes. Using transcriptome profiling in single cells, we discover that the loss of essential lncRNAs impairs cell-cycle progression and drives apoptosis. Many essential lncRNAs demonstrate dynamic expression across tissues during development. Using ∼9,000 primary tumors, we pinpoint those lncRNAs whose expression in tumors correlates with survival, yielding new biomarkers and potential therapeutic targets. This transcriptome-wide survey of functional lncRNAs advances our understanding of noncoding transcripts and demonstrates the potential of transcriptome-scale noncoding screens with Cas13.

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