Abstract
Recent single-cell RNA-sequencing atlases have surveyed and identified major cell types across different mouse tissues. Here, we computationally reconstruct gene regulatory networks from three major mouse cell atlases to capture functional regulators critical for cell identity, while accounting for a variety of technical differences, including sampled tissues, sequencing depth, and author assigned cell type labels. Extracting the regulatory crosstalk from mouse atlases, we identify and distinguish global regulons active in multiple cell types from specialised cell type-specific regulons. We demonstrate that regulon activities accurately distinguish individual cell types, despite differences between individual atlases. We generate an integrated network that further uncovers regulon modules with coordinated activities critical for cell types, and validate modules using available experimental data. Inferring regulatory networks during myeloid differentiation from wild-type and Irf8 KO cells, we uncover functional contribution of Irf8 regulon activity and composition towards monocyte lineage. Our analysis provides an avenue to further extract and integrate the regulatory crosstalk from single-cell expression data.
Highlights
Multicellular organisms are composed of different tissues consisting of varied cell types that are regulated at the single-cell level
We applied our two-step approach to individual atlases, that is, Tabula Muris (TM)-10× (Fig S2B), TM Smart-seq2 (TM-SS2; Fig S3A), Mouse Cell Atlas (MCA) (Fig S3B), and to all atlases integrated together (Fig S4)
Our integrative analysis on three atlases uncovers global regulon modules that operate on multiple cells types, as well as specialised regulons critical for cell type definition and identity
Summary
Multicellular organisms are composed of different tissues consisting of varied cell types that are regulated at the single-cell level. The underlying expression heterogeneity between single cells can be attributed to finer grouping of cell types, inherent stochasticity and variations in underlying functional and regulatory crosstalk [3, 4, 5, 6]. Single cells maintain their cell state and respond to a variety of external cues by modulating transcriptional changes, which are governed by complex generegulatory networks (GRNs) [7, 8]. Recent computational approaches have enabled inference of the gene regulatory circuitry from scRNA-seq datasets [9, 12, 13, 14, 15, 16]
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