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Enhanced Integrated Gradients: improving interpretability of deep learning models using splicing codes as a case study

Anupama Jha, Joseph K. Aicher, Matthew R. Gazzara, Deependra Singh, Yoseph Barash

2020Genome biology92 citationsDOIOpen Access PDF

Abstract

Despite the success and fast adaptation of deep learning models in biomedical domains, their lack of interpretability remains an issue. Here, we introduce Enhanced Integrated Gradients (EIG), a method to identify significant features associated with a specific prediction task. Using RNA splicing prediction as well as digit classification as case studies, we demonstrate that EIG improves upon the original Integrated Gradients method and produces sets of informative features. We then apply EIG to identify A1CF as a key regulator of liver-specific alternative splicing, supporting this finding with subsequent analysis of relevant A1CF functional (RNA-seq) and binding data (PAR-CLIP).

Topics & Concepts

InterpretabilityRNA splicingBiologyComputational biologyRegulatorAlternative splicingArtificial intelligenceKey (lock)Adaptation (eye)Machine learningTask (project management)Deep learningRNAComputer scienceGeneticsGeneNeuroscienceMessenger RNAEngineeringEcologySystems engineeringRNA Research and SplicingRNA modifications and cancerRNA and protein synthesis mechanisms