Abstract
A major drawback of single cell ATAC (scATAC) is its sparsity, i.e. open chromatin regions with no reads due to loss of DNA material during the scATAC-seq protocol. We propose scOpen, a computational method for imputing and quantifying the open chromatin status of regulatory regions from sparse scATAC-seq experiments. We show that scOpen improves crucial down-stream analysis steps of scATAC-seq data as clustering, visualisation, cis-regulatory DNA interactions and delineation of regulatory features. We demonstrate the power of scOpen to dissect regulatory changes in the development of fibrosis in the kidney. This identified a novel role of Runx1 and target genes by promoting fibroblast to myofibroblast differentiation driving kidney fibrosis.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
We have expanded the benchmarking of imputation methods by both additional data sets, methods and evaluation strategies. The manuscript also includes more detailed analysis of cis-regulatory DNA-interactions and well as additional validations for RUNX1 target genes.