Alessandro Cavallo , Giorgio Anselmi , Thomas A. Milne , Marella F.T.R. de Bruijn
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引用次数: 0
Abstract
The first haematopoietic stem and progenitor cells (HSPCs) in the embryo arise through a process known as endothelial-to-haematopoietic transition (EHT). In a subset of endothelial cells referred to as haemogenic endothelium (HE), the endothelial transcriptional programme is gradually replaced by a haematopoietic one, promoting haematopoietic commitment and ultimately EHT. This process is critically dependent on the transcription factor RUNX1. There is currently limited knowledge on the transcriptional regulation and downstream function of RUNX1 during human EHT. Here, using an in vitro human induced pluripotent stem cell (hiPSC) differentiation model, we identified five candidate EHT RUNX1 enhancers, characterised by H3K27ac and open chromatin, one of which is only accessible in HE and four are accessible in haematopoietic cells. Through gene regulatory network (GRN) analysis, performed on joint single-cell chromatin accessibility and gene expression profiling data, we identified a set of candidate upstream RUNX1 activators and repressors. These included known RUNX1 regulators (e.g. GATA2, MEIS1, EPAS1) as well as potentially novel ones. To identify the downstream target genes of RUNX1, we profiled RUNX1-binding sites genome-wide in hiPSC-derived HE, where most of these sites were not acetylated and were associated with endothelial genes, suggesting RUNX1 might directly repress the endothelial programme. Together, our data are expected to improve our understanding of the regulatory mechanisms underlying human EHT.
期刊介绍:
Experimental Hematology publishes new findings, methodologies, reviews and perspectives in all areas of hematology and immune cell formation on a monthly basis that may include Special Issues on particular topics of current interest. The overall goal is to report new insights into how normal blood cells are produced, how their production is normally regulated, mechanisms that contribute to hematological diseases and new approaches to their treatment. Specific topics may include relevant developmental and aging processes, stem cell biology, analyses of intrinsic and extrinsic regulatory mechanisms, in vitro behavior of primary cells, clonal tracking, molecular and omics analyses, metabolism, epigenetics, bioengineering approaches, studies in model organisms, novel clinical observations, transplantation biology and new therapeutic avenues.