Single cell transcriptional and chromatin accessibility profiling redefine cellular heterogeneity in the adult human kidney
Updated October 11, 2023The integration of single cell transcriptome and chromatin accessibility datasets enables a deeper understanding of cell heterogeneity. We performed single nucleus ATAC (snATAC-seq) and RNA (snRNA-seq) sequencing to generate paired, cell-type-specific chromatin accessibility and transcriptional profiles of the adult human kidney. We demonstrate that snATAC-seq is comparable to snRNA-seq in the assignment of cell identity and can further refine our understanding of functional heterogeneity in the nephron. The majority of differentially accessible chromatin regions are localized to promoters and a significant proportion are closely associated with differentially expressed genes. Cell-type-specific enrichment of transcription factor binding motifs implicates the activation of NF-κB that promotes VCAM1 expression and drives transition between a subpopulation of proximal tubule epithelial cells. Our multi-omics approach improves the ability to detect unique cell states within the kidney and redefines cellular heterogeneity in the proximal tubule and thick ascending limb.
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Atlas
Analysis Portals
Project Label
SinglecelltranscriptionalandchromatinaccessibilitySpecies
Homo sapiens
Sample Type
specimens
Anatomical Entity
kidney
Organ Part
cortex of kidney
Selected Cell Types
Unspecified
Disease Status (Specimen)
Unspecified
Disease Status (Donor)
Development Stage
Library Construction Method
Nucleic Acid Source
single nucleus
Paired End
falseFile Format
fastq
Cell Count Estimate
98.5kDonor Count
5