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Single-cell ultra-high-throughput multiplexed chromatin and RNA profiling reveals gene regulatory dynamics

Sara Lobato-Moreno, Umut Yildiz, Annique Claringbould, Nila H. Servaas, Evi P. Vlachou, Christian Arnold, Hanke Gwendolyn Bauersachs, Víctor Campos-Fornés, Minyoung Kim, Ivan Berest, Karin D. Prummel, Kyung‐Min Noh, Mikael Marttinen, Judith B. Zaugg

2025Nature Methods22 citationsDOIOpen Access PDF

Abstract

Enhancers and transcription factors (TFs) are crucial in regulating cellular processes. Current multiomic technologies to study these elements in gene regulatory mechanisms lack multiplexing capability and scalability. Here we present single-cell ultra-high-throughput multiplexed sequencing (SUM-seq) for co-assaying chromatin accessibility and gene expression in single nuclei. SUM-seq enables profiling hundreds of samples at the million cell scale and outperforms current high-throughput single-cell methods. We demonstrate the capability of SUM-seq to (1) resolve temporal gene regulation of macrophage M1 and M2 polarization to bridge TF regulatory networks and immune disease genetic variants, (2) define the regulatory landscape of primary T helper cell subsets and (3) dissect the effect of perturbing lineage TFs via arrayed CRISPR screens in spontaneously differentiating human induced pluripotent stem cells. SUM-seq offers a cost-effective, scalable solution for ultra-high-throughput single-cell multiomic sequencing, accelerating the unraveling of complex gene regulatory networks in cell differentiation, responses to perturbations and disease studies.

Topics & Concepts

BiologyChromatinComputational biologyRegulation of gene expressionGene expression profilingGeneEnhancerCRISPRTranscription factorGene expressionGeneticsSingle-cell and spatial transcriptomicsCRISPR and Genetic EngineeringAdvanced biosensing and bioanalysis techniques
Single-cell ultra-high-throughput multiplexed chromatin and RNA profiling reveals gene regulatory dynamics | Litcius