Single-cell RNA-seq profiling of small intestinal epithelium from whole body miR-375 knockout mice (baseline)

MicroRNAs (miRNAs) are important post-transcriptional gene regulators in organ development. To explore candidate roles for miRNAs in prenatal SI lineage specification in humans, we used a multi-omic analysis strategy in a directed differentiation model that programs human pluripotent stem cells toward the SI lineage. We leveraged small RNA-seq to define the changing miRNA landscape, and integrated chromatin run-on sequencing (ChRO-seq) and RNA-seq to define genes subject to significant post-transcriptional regulation across the different stages of differentiation. Our analyses showed that the elevation of miR-182 and reduction of miR-375 are key events during SI lineage specification. We demonstrated that loss of miR-182 leads to an increase in the foregut marker SOX2. We also used single-cell analyses in murine adult intestinal crypts to support a life-long role for miR-375 in the regulation of Zfp36l2. We also uncovered opposing roles of SMAD4 and WNT signaling in regulating miR-375 expression during SI lineage specification. Beyond the mechanisms highlighted in this study, we also present a web-based application for exploration of post-transcriptional regulation and miRNA-mediated control in the context of early human SI development. To validate candidate miR-375 target genes that are identified through multi-omics analyses, we performed single-cell RNA-seq of small intestinal epithelium (isolated crypts from the jejunal segment) from wildtype and whole body miR-375 knockout mice. Be noted that the single-cell RNA-seq data of wildtype mice has been published through GSE178826.