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DISC: a highly scalable and accurate inference of gene expression and structure for single-cell transcriptomes using semi-supervised deep learning

Yao He, Hao Yuan, Cheng Wu, Zhi Xie

2020Genome biology41 citationsDOIOpen Access PDF

Abstract

Dropouts distort gene expression and misclassify cell types in single-cell transcriptome. Although imputation may improve gene expression and downstream analysis to some degree, it also inevitably introduces false signals. We develop DISC, a novel deep learning network with semi-supervised learning to infer gene structure and expression obscured by dropouts. Compared with seven state-of-the-art imputation approaches on ten real-world datasets, we show that DISC consistently outperforms the other approaches. Its applicability, scalability, and reliability make DISC a promising approach to recover gene expression, enhance gene and cell structures, and improve cell type identification for sparse scRNA-seq data.

Topics & Concepts

InferenceImputation (statistics)Artificial intelligenceScalabilityBiologyComputational biologyGene regulatory networkTranscriptomeGene expressionComputer scienceGene expression profilingDeep learningGeneIdentification (biology)Machine learningPattern recognition (psychology)Missing dataGeneticsDatabaseBotanySingle-cell and spatial transcriptomicsExtracellular vesicles in diseaseAdvanced biosensing and bioanalysis techniques
DISC: a highly scalable and accurate inference of gene expression and structure for single-cell transcriptomes using semi-supervised deep learning | Litcius