Identification of Human Short Introns

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2017 May 19

PMID 28520720

Citations 10

Authors

Emmanuel L Abebrese

Syed H Ali

Zachary R Arnold

Victoria M Andrews

Katharine Armstrong

Lindsay Burns

Hannah R Crowder

R Thomas Day Jr

Daniel G Hsu

Katherine Jarrell

Grace Lee

Yi Luo

Daphine Mugayo

Zain Raza

Kyle Friend

Affiliations

Soon will be listed here.

Abstract

Canonical pre-mRNA splicing requires snRNPs and associated splicing factors to excise conserved intronic sequences, with a minimum intron length required for efficient splicing. Non-canonical splicing-intron excision without the spliceosome-has been documented; most notably, some tRNAs and the XBP1 mRNA contain short introns that are not removed by the spliceosome. There have been some efforts to identify additional short introns, but little is known about how many short introns are processed from mRNAs. Here, we report an approach to identify RNA short introns from RNA-Seq data, discriminating against small genomic deletions. We identify hundreds of short introns conserved among multiple human cell lines. These short introns are often alternatively spliced and are found in a variety of RNAs-both mRNAs and lncRNAs. Short intron splicing efficiency is increased by secondary structure, and we detect both canonical and non-canonical short introns. In many cases, splicing of these short introns from mRNAs is predicted to alter the reading frame and change protein output. Our findings imply that standard gene prediction models which often assume a lower limit for intron size fail to predict short introns effectively. We conclude that short introns are abundant in the human transcriptome, and short intron splicing represents an added layer to mRNA regulation.

Citing Articles

Refining clinically relevant parameters for mis-splicing risk in shortened introns with donor-to-branchpoint space constraint.

Zhang K, Joshi H, Marchant R, Bryen S, Dawes R, Yuen M Eur J Hum Genet. 2024; 32(8):972-979.

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Introns: the "dark matter" of the eukaryotic genome.

Girardini K, Olthof A, Kanadia R Front Genet. 2023; 14:1150212.

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