Abstract

Single-cell RNA sequencing technologies suffer from many sources of technical noise, including under-sampling of mRNA molecules, often termed "dropout," which can severely obscure important gene-gene relationships. To address this, we developed MAGIC (Markov affinity-based graph imputation of cells), a method that shares information across similar cells, via data diffusion, to denoise the cell count matrix and fill in missing transcripts. We validate MAGIC on several biological systems and find it effective at recovering gene-gene relationships and additional structures. Applied to the epithilial to mesenchymal transition, MAGIC reveals a phenotypic continuum, with the majority of cells residing in intermediate states that display stem-like signatures, and infers known and previously uncharacterized regulatory interactions, demonstrating that our approach can successfully uncover regulatory relations without perturbations.

Keywords

BiologyComputational biologyGeneImputation (statistics)Gene regulatory networkMAGIC (telescope)GeneticsGene expressionMissing dataComputer scienceMachine learningPhysics

MeSH Terms

AlgorithmsCell LineEpistasisGeneticGene Expression ProfilingGene Regulatory NetworksHumansMarkov ChainsMicroRNAsRNAMessengerSequence AnalysisRNASingle-Cell AnalysisSoftware

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Publication Info

Year
2018
Type
article
Volume
174
Issue
3
Pages
716-729.e27
Citations
1729
Access
Closed

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Cite This

David van Dijk, Roshan Sharma, Juozas Nainys et al. (2018). Recovering Gene Interactions from Single-Cell Data Using Data Diffusion. Cell , 174 (3) , 716-729.e27. https://doi.org/10.1016/j.cell.2018.05.061

Identifiers

DOI
10.1016/j.cell.2018.05.061
PMID
29961576
PMCID
PMC6771278

Data Quality

Data completeness: 90%