Abstract
BackgroundAdenosine-to-inosine (A-to-I) editing is a site-selective post-transcriptional alteration of double-stranded RNA by ADAR deaminases that is crucial for homeostasis and development. Recently the Mouse Genomes Project generated genome sequences for 17 laboratory mouse strains and rich catalogues of variants. We also generated RNA-seq data from whole brain RNA from 15 of the sequenced strains.ResultsHere we present a computational approach that takes an initial set of transcriptome/genome mismatch sites and filters these calls taking into account systematic biases in alignment, single nucleotide variant calling, and sequencing depth to identify RNA editing sites with high accuracy. We applied this approach to our panel of mouse strain transcriptomes identifying 7,389 editing sites with an estimated false-discovery rate of between 2.9 and 10.5%. The overwhelming majority of these edits were of the A-to-I type, with less than 2.4% not of this class, and only three of these edits could not be explained as alignment artifacts. We validated 24 novel RNA editing sites in coding sequence, including two non-synonymous edits in the Cacna1d gene that fell into the IQ domain portion of the Cav1.2 voltage-gated calcium channel, indicating a potential role for editing in the generation of transcript diversity.ConclusionsWe show that despite over two million years of evolutionary divergence, the sites edited and the level of editing at each site is remarkably consistent across the 15 strains. In the Cds2 gene we find evidence for RNA editing acting to preserve the ancestral transcript sequence despite genomic sequence divergence.
Highlights
Adenosine-to-inosine (A-to-I) editing is a site-selective post-transcriptional alteration of doublestranded RNA by adenosine deaminase acting on RNA (ADAR) deaminases that is crucial for homeostasis and development
We present the first comprehensive survey of RNA editing in the mouse genome across a diverse set of 15 mouse strains that together represent all of the major laboratory mouse lineages
Higuchi et al [21] experimentally showed that ADARs require a duplex structure that does not depend on the sequence surrounding the edited position and we find that 25% of RNA editing sites have neither a T immediately 5’ nor a G immediately 3’ of the edited base
Summary
Adenosine-to-inosine (A-to-I) editing is a site-selective post-transcriptional alteration of doublestranded RNA by ADAR deaminases that is crucial for homeostasis and development. We generated RNA-seq data from whole brain RNA from 15 of the sequenced strains. The adenosine deaminase acting on RNA (ADAR) family of enzymes is capable of modifying adenosine residues to inosines [1]. The ADARs bind to double-stranded regions of RNA and can modify multiple neighboring adenosines until a tolerance level is reached and the structure of the RNA becomes destabilized [2]. RNA editing in coding regions can lead to alteration in protein function and increased transcript diversity. The best known example of this is editing of neural serotonin receptor HTR2C gene transcripts, which are edited at five sites in close proximity to each other [3], thereby producing a diverse repertoire of 28 mRNAs and 20 protein isoforms [4].
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