Inferring population dynamics from single-cell RNA-sequencing time series data.

IF: 68.164

Cited by: 74

Abstract

Recent single-cell RNA-sequencing studies have suggested that cells follow continuous transcriptomic trajectories in an asynchronous fashion during development. However, observations of cell flux along trajectories are confounded with population size effects in snapshot experiments and are therefore hard to interpret. In particular, changes in proliferation and death rates can be mistaken for cell flux. Here we present pseudodynamics, a mathematical framework that reconciles population dynamics with the concepts underlying developmental trajectories inferred from time-series single-cell data. Pseudodynamics models population distribution shifts across trajectories to quantify selection pressure, population expansion, and developmental potentials. Applying this model to time-resolved single-cell RNA-sequencing of T-cell and pancreatic beta cell maturation, we characterize proliferation and apoptosis rates and identify key developmental checkpoints, data inaccessible to existing approaches.

Keywords

Seurat

Spatial reconstruction

MeSH terms

Animals

Apoptosis

Biotechnology

Cell Differentiation

Cell Proliferation

Female

Insulin-Secreting Cells

Likelihood Functions

Male

Mice

Mice, Inbred C57BL

Mice, Knockout

Models, Biological

Mouse Embryonic Stem Cells

Sequence Analysis, RNA

Single-Cell Analysis

T-Lymphocytes

Time Factors

Authors

Fischer, David S

Fiedler, Anna K

Kernfeld, Eric M

Genga, Ryan M J

Bastidas-Ponce, Aimée

Bakhti, Mostafa

Lickert, Heiko

Hasenauer, Jan

Maehr, Rene

Theis, Fabian J

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