Full-length Transcript Sequencing of Human and Mouse Cerebral Cortex Identifies Widespread Isoform Diversity and Alternative Splicing

Overview

Journal Cell Rep

Publisher Cell Press

Specialties Biology
Cell Biology
Molecular Biology

Date 2021 Nov 17

PMID 34788620

Citations 64

Authors

Szi Kay Leung

Aaron R Jeffries

Isabel Castanho

Ben T Jordan

Karen Moore

Jonathan P Davies

Emma L Dempster

Nicholas J Bray

Paul ONeill

Elizabeth Tseng

Zeshan Ahmed

David A Collier

Erin D Jeffery

Shyam Prabhakar

Leonard Schalkwyk

Connor Jops

Michael J Gandal

Gloria M Sheynkman

Eilis Hannon

Jonathan Mill

Affiliations

Soon will be listed here.

Abstract

Alternative splicing is a post-transcriptional regulatory mechanism producing distinct mRNA molecules from a single pre-mRNA with a prominent role in the development and function of the central nervous system. We used long-read isoform sequencing to generate full-length transcript sequences in the human and mouse cortex. We identify novel transcripts not present in existing genome annotations, including transcripts mapping to putative novel (unannotated) genes and fusion transcripts incorporating exons from multiple genes. Global patterns of transcript diversity are similar between human and mouse cortex, although certain genes are characterized by striking differences between species. We also identify developmental changes in alternative splicing, with differential transcript usage between human fetal and adult cortex. Our data confirm the importance of alternative splicing in the cortex, dramatically increasing transcriptional diversity and representing an important mechanism underpinning gene regulation in the brain. We provide transcript-level data for human and mouse cortex as a resource to the scientific community.

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