In order to generate the catalogue of tissue-specific alternative splicing events and RNA-editing sites, we have collected sequencing samples for public and in-house tissue-specific RNA of fifteen bilaterian species, that includes four mammals: human, mouse, cow and opossum; four non-mammalian vertebrates: chicken, frog, zebrafish and elephant shark and seven non-vertebrate species: amphioxus, sea urchin, centipede, fruitfly, mayfly, honey bee and octopus of eight major tissue groups: Neural, Muscle, Epithelial, Digestive tract, Kidney, Adipose, Ovary and Testis. All the gene and exon quantifications were performed using vast-tools (
https://github.com/vastgroup/vast-tools(se abrirá en una nueva ventana)) and for detection of RNA-editing sites we have made use of SAILOR (
https://github.com/YeoLab/sailor(se abrirá en una nueva ventana)). In average, we found that in average seven percent of the exons analyzed in all species are alternatively spliced, with human presenting the highest amount of AS exons. In terms of tissue-specificity, we obtained that for the majority of the species tested, the neural, testis and muscle tissue groups present the highest number of tissue-specific exons exons. All the events obtained from this analysis will be accessible soon at VastDB (
http://vastdb.crg.eu/(se abrirá en una nueva ventana)) were the information for human, mouse and chicken is already publicly available.
To evaluate the evolutionary conservation of tissue-specific exons, we have developed a computational pipeline to determine exon orthology of any species with genomic information available. Currently, we are working to adapt this pipeline also for the identification of conserved RNA-editing sites. Making use of out pipeline to the aforementioned species resulted in about 80% of the exons to be assigned as conserved between at least one pair of species. Moreover, for human tissue-specific exons, we found that 52% of the neural-specific exons and 46% of the muscle-specific exons are conserved among all vertebrates analyzed. In particular, the set of human highly conserved neural regulated events found in this project denote a valuable resource for future experimentation to evaluate the role of these post-transcriptional events in neural physiology and neurological diseases.
Finally, we have selected a couple of highly conserved neural AS events to test their role in the nervous system of the fruitfly Drosophila melanogaster. We found that deletion of these AS events in the nervous system results in flies with severe neurological defects, supporting the functions of these events in the proper physiology of neurons.