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Splice2Deep: An ensemble of deep convolutional neural networks for improved splice site prediction in genomic DNA

Somayah Albaradei, Arturo Magana-Mora, Maha A. Thafar, Mahmut Uludağ, Vladimir B. Bajić, Takashi Gojobori, Magbubah Essack, Boris R. Janković

2020Gene60 citationsDOIOpen Access PDF

Abstract

BACKGROUND: The accurate identification of the exon/intron boundaries is critical for the correct annotation of genes with multiple exons. Donor and acceptor splice sites (SS) demarcate these boundaries. Therefore, deriving accurate computational models to predict the SS are useful for functional annotation of genes and genomes, and for finding alternative SS associated with different diseases. Although various models have been proposed for the in silico prediction of SS, improving their accuracy is required for reliable annotation. Moreover, models are often derived and tested using the same genome, providing no evidence of broad application, i.e. to other poorly studied genomes. RESULTS: . Results demonstrate that the models efficiently detect SS in other organisms not considered during the training of the models. Compared to the state-of-the-art tools, Splice2Deep models achieved significantly reduced average error rates of 41.97% and 28.51% for acceptor and donor SS, respectively. Moreover, the Splice2Deep cross-organism validation demonstrates that models correctly identify conserved genomic elements enabling annotation of SS in new genomes by choosing the taxonomically closest model. CONCLUSIONS: The results of our study demonstrated that Splice2Deep both achieved a considerably reduced error rate compared to other state-of-the-art models and the ability to accurately recognize SS in other organisms for which the model was not trained, enabling annotation of poorly studied or newly sequenced genomes. Splice2Deep models are implemented in Python using Keras API; the models and the data are available at https://github.com/SomayahAlbaradei/Splice_Deep.git.

Topics & Concepts

BiologyAnnotationGenomeComputational biologyspliceCaenorhabditis elegansIn silicoConvolutional neural networkModel organismGene AnnotationGeneticsComputer scienceArtificial intelligenceGeneMachine Learning in BioinformaticsRNA Research and SplicingGenomics and Chromatin Dynamics