RENGE infers gene regulatory networks using time-series single-cell RNA-seq data with CRISPR perturbations.
Masato IshikawaSeiichi SuginoYoshie MasudaYusuke TarumotoYusuke SetoNobuko TaniyamaFumi WagaiYuhei YamauchiYasuhiro KojimaHisanori KiryuKosuke YusaMototsugu EirakuAtsushi MochizukiPublished in: Communications biology (2023)
Single-cell RNA-seq analysis coupled with CRISPR-based perturbation has enabled the inference of gene regulatory networks with causal relationships. However, a snapshot of single-cell CRISPR data may not lead to an accurate inference, since a gene knockout can influence multi-layered downstream over time. Here, we developed RENGE, a computational method that infers gene regulatory networks using a time-series single-cell CRISPR dataset. RENGE models the propagation process of the effects elicited by a gene knockout on its regulatory network. It can distinguish between direct and indirect regulations, which allows for the inference of regulations by genes that are not knocked out. RENGE therefore outperforms current methods in the accuracy of inferring gene regulatory networks. When used on a dataset we derived from human-induced pluripotent stem cells, RENGE yielded a network consistent with multiple databases and literature. Accurate inference of gene regulatory networks by RENGE would enable the identification of key factors for various biological systems.
Keyphrases
- single cell
- rna seq
- genome wide
- induced pluripotent stem cells
- genome editing
- crispr cas
- high throughput
- dna methylation
- copy number
- big data
- systematic review
- endothelial cells
- electronic health record
- high resolution
- genome wide identification
- transcription factor
- gene expression
- gold nanoparticles
- artificial intelligence
- wild type
- genome wide analysis
- reduced graphene oxide