Litcius/Paper detail

Deep learning-based cell-specific gene regulatory networks inferred from single-cell multiome data

Junlin Xu, Changcheng Lu, Shuting Jin, Yajie Meng, Xiangzheng Fu, Xiangxiang Zeng, Ruth Nussinov, Feixiong Cheng

2025Nucleic Acids Research38 citationsDOIOpen Access PDF

Abstract

Gene regulatory networks (GRNs) provide a global representation of how genetic/genomic information is transferred in living systems and are a key component in understanding genome regulation. Single-cell multiome data provide unprecedented opportunities to reconstruct GRNs at fine-grained resolution. However, the inference of GRNs is hindered by insufficient single omic profiles due to the characteristic high loss rate of single-cell sequencing data. In this study, we developed scMultiomeGRN, a deep learning framework to infer transcription factor (TF) regulatory networks via unique integration of single-cell genomic (single-cell RNA sequencing) and epigenomic (single-cell ATAC sequencing) data. We create scMultiomeGRN to elucidate these networks by conceptualizing TF network graph structures. Specifically, we build modality-specific neighbor aggregators and cross-modal attention modules to learn latent representations of TFs from single-cell multi-omics. We demonstrate that scMultiomeGRN outperforms state-of-the-art models on multiple benchmark datasets involved in diseases and health. Via scMultiomeGRN, we identified Alzheimer's disease-relevant regulatory network of SPI1 and RUNX1 for microglia. In summary, scMultiomeGRN offers a deep learning framework to identify cell type-specific gene regulatory network from single-cell multiome data.

Topics & Concepts

BiologyGeneComputational biologyGene regulatory networkGeneticsCellGene expressionSingle-cell and spatial transcriptomicsGene Regulatory Network AnalysisCell Image Analysis Techniques