Deep Splicing Plasticity of the Human Adenovirus Type 5 Transcriptome Drives Virus Evolution

Overview

Journal Commun Biol

Specialty Biology

Date 2020 Mar 15

PMID 32170151

Citations 30

Authors

Iah Donovan-Banfield

Andrew S Turnell

Julian A Hiscox

Keith N Leppard

David A Matthews

Affiliations

Soon will be listed here.

Abstract

Viral genomes have high gene densities and complex transcription strategies rendering transcriptome analysis through short-read RNA-seq approaches problematic. Adenovirus transcription and splicing is especially complex. We used long-read direct RNA sequencing to study adenovirus transcription and splicing during infection. This revealed a previously unappreciated complexity of alternative splicing and potential for secondary initiating codon usage. Moreover, we find that most viral transcripts tend to shorten polyadenylation lengths as infection progresses. Development of an open reading frame centric bioinformatics analysis pipeline provided a deeper quantitative and qualitative understanding of adenovirus's genetic potential. Across the viral genome adenovirus makes multiple distinctly spliced transcripts that code for the same protein. Over 11,000 different splicing patterns were recorded across the viral genome, most occurring at low levels. This low-level use of alternative splicing patterns potentially enables the virus to maximise its coding potential over evolutionary timescales.

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