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Generalized and scalable trajectory inference in single-cell omics data with VIA

Shobana V. Stassen, Gwinky G. K. Yip, Kenneth K. Y. Wong, Joshua W. K. Ho, Kevin K. Tsia

2021Nature Communications110 citationsDOIOpen Access PDF

Abstract

Inferring cellular trajectories using a variety of omic data is a critical task in single-cell data science. However, accurate prediction of cell fates, and thereby biologically meaningful discovery, is challenged by the sheer size of single-cell data, the diversity of omic data types, and the complexity of their topologies. We present VIA, a scalable trajectory inference algorithm that overcomes these limitations by using lazy-teleporting random walks to accurately reconstruct complex cellular trajectories beyond tree-like pathways (e.g., cyclic or disconnected structures). We show that VIA robustly and efficiently unravels the fine-grained sub-trajectories in a 1.3-million-cell transcriptomic mouse atlas without losing the global connectivity at such a high cell count. We further apply VIA to discovering elusive lineages and less populous cell fates missed by other methods across a variety of data types, including single-cell proteomic, epigenomic, multi-omics datasets, and a new in-house single-cell morphological dataset.

Topics & Concepts

Computer scienceScalabilityInferenceComputational biologyVariety (cybernetics)EpigenomicsTree (set theory)BiologyArtificial intelligenceMathematicsBiochemistryDNA methylationDatabaseGene expressionGeneMathematical analysisSingle-cell and spatial transcriptomicsCell Image Analysis TechniquesGene expression and cancer classification
Generalized and scalable trajectory inference in single-cell omics data with VIA | Litcius