DeepVelo: deep learning extends RNA velocity to multi-lineage systems with cell-specific kinetics

被引:0
作者
Haotian Cui
Hassaan Maan
Maria C. Vladoiu
Jiao Zhang
Michael D. Taylor
Bo Wang
机构
[1] University Health Network,Peter Munk Cardiac Center
[2] University of Toronto,Department of Computer Science
[3] Vector Institute,Department of Medical Biophysics
[4] University of Toronto,Department of Pathology and Molecular Medicine
[5] McMaster University,The Arthur and Sonia Labatt Brain Tumor Research Centre
[6] The Hospital for Sick Children,Developmental and Stem Cell Biology Program
[7] The Hospital for Sick Children,Department of Laboratory Medicine and Pathobiology
[8] Baylor College of Medicine,undefined
[9] Texas Children’s Hospital,undefined
[10] University of Toronto,undefined
来源
Genome Biology | / 25卷
关键词
RNA velocity; Single-cell RNA sequencing; Deep Learning; Development; Cancer;
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摘要
Existing RNA velocity estimation methods strongly rely on predefined dynamics and cell-agnostic constant transcriptional kinetic rates, assumptions often violated in complex and heterogeneous single-cell RNA sequencing (scRNA-seq) data. Using a graph convolution network, DeepVelo overcomes these limitations by generalizing RNA velocity to cell populations containing time-dependent kinetics and multiple lineages. DeepVelo infers time-varying cellular rates of transcription, splicing, and degradation, recovers each cell’s stage in the differentiation process, and detects functionally relevant driver genes regulating these processes. Application to various developmental and pathogenic processes demonstrates DeepVelo’s capacity to study complex differentiation and lineage decision events in heterogeneous scRNA-seq data.
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