Abstract
Mutually exclusive splicing is an important mechanism for expanding protein diversity. An extreme example is the Down syndrome cell adhesion molecular (Dscam1) gene of insects, containing four clusters of variable exons (exons 4, 6, 9, and 17), which potentially generates tens of thousands of protein isoforms through mutually exclusive splicing, of which regulatory mechanisms are still elusive. Here, we systematically analyzed the variable exon 4, 6, and 9 clusters of Dscam1 in Coleoptera species. Through comparative genomics and RNA secondary structure prediction, we found apparent evidence that the evolutionarily conserved RNA base pairing mediates mutually exclusive splicing in the Dscam1 exon 4 cluster. In contrast to the fly exon 6, most exon 6 selector sequences in Coleoptera species are partially located in the variable exon region. Besides, bidirectional RNA–RNA interactions are predicted to regulate the mutually exclusive splicing of variable exon 9 of Dscam1. Although the docking sites in exon 4 and 9 clusters are clade specific, the docking sites-selector base pairing is conserved in secondary structure level. In short, our result provided a mechanistic framework for the application of long-range RNA base pairings in regulating the mutually exclusive splicing of Coleoptera Dscam1.
Highlights
Alternative splicing is an important precursor RNA processing method to increase protein diversity in eukaryotes (Nilsen and Graveley, 2010; Pandey et al, 2020; Suresh et al, 2020)
The mutually exclusive alternative splicing model of Dscam1 exon 6 cluster guided by competitive secondary structure was proposed as early as 2005
Our study predicted the secondary structure in the Coleoptera exon 6 cluster, and most selector sequences were partly located in the exons
Summary
Alternative splicing is an important precursor RNA processing method to increase protein diversity in eukaryotes (Nilsen and Graveley, 2010; Pandey et al, 2020; Suresh et al, 2020). Pre-messenger RNA (pre-mRNA) alternative splicing has recently been thought to be related to the aging process and longevity (Bhadra et al, 2020). There are five main types of alternative splicing, including intron retention, exon skipping, alternative 3 splice sites, alternative 5 splice sites, and mutually exclusive splicing (Nilsen and Graveley, 2010; Zhang et al, 2016; Hatje et al, 2017; Jin et al, 2018). Exclusive splicing is a specific type of alternative splicing; in a tandem exon array, only one variable
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