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Predicting protein interaction network perturbation by alternative splicing with semi-supervised learning

Oleksandr Narykov, Nathan Johnson, Dmitry Korkin

2021Cell Reports11 citationsDOIOpen Access PDF

Abstract

Alternative splicing introduces an additional layer of protein diversity and complexity in regulating cellular functions that can be specific to the tissue and cell type, physiological state of a cell, or disease phenotype. Recent high-throughput experimental studies have illuminated the functional role of splicing events through rewiring protein-protein interactions; however, the extent to which the macromolecular interactions are affected by alternative splicing has yet to be fully understood. In silico methods provide a fast and cheap alternative to interrogating functional characteristics of thousands of alternatively spliced isoforms. Here, we develop an accurate feature-based machine learning approach that predicts whether a protein-protein interaction carried out by a reference isoform is perturbed by an alternatively spliced isoform. Our method, called the alternatively spliced interactions prediction (ALT-IN) tool, is compared with the state-of-the-art PPI prediction tools and shows superior performance, achieving 0.92 in precision and recall values.

Topics & Concepts

Alternative splicingComputational biologyIn silicoRNA splicingGene isoformProtein–protein interactionProtein isoformPhenotypeBiologyComputer scienceProtein Interaction NetworksMachine learningArtificial intelligenceBioinformaticsCell biologyGeneGeneticsRNABioinformatics and Genomic NetworksProtein Structure and DynamicsRNA Research and Splicing
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