Abstract
During embryogenesis, vascular development relies on a handful of transcription factors that instruct cell fate in a distinct sub-population of the endothelium (1). The SOXF proteins that comprise SOX7, 17 and 18, are molecular switches modulating arterio-venous and lymphatic endothelial differentiation (2,3). Here, we show that, in the SOX-F family, only SOX18 has the ability to switch between a monomeric and a dimeric form. We characterized the SOX18 dimer in binding assays in vitro, and using a split-GFP reporter assay in a zebrafish model system in vivo. We show that SOX18 dimerization is driven by a novel motif located in the vicinity of the C-terminus of the DNA binding region. Insertion of this motif in a SOX7 monomer forced its assembly into a dimer. Genome-wide analysis of SOX18 binding locations on the chromatin revealed enrichment for a SOX dimer binding motif, correlating with genes with a strong endothelial signature. Using a SOX18 small molecule inhibitor that disrupts dimerization, we revealed that dimerization is important for transcription. Overall, we show that dimerization is a specific feature of SOX18 that enables the recruitment of key endothelial transcription factors, and refines the selectivity of the binding to discrete genomic locations assigned to endothelial specific genes.
Highlights
Understanding how transcription factors (TFs) orchestrate gene expression to instruct a phenotypic output is fundamental to biology and future therapeutics
In order to characterize the behaviour of fulllength SOX7, SOX17 and SOX18 proteins, we turned to cell-free protein translation
We describe the molecular basis for the dimerization of the SOX18 transcription factor, a key player during endothelial cell fate determination
Summary
Understanding how transcription factors (TFs) orchestrate gene expression to instruct a phenotypic output is fundamental to biology and future therapeutics. Many members of the SOX SRYrelated High-Mobility Group (HMG) box family act as central regulators of gene expression to govern cell fate in a variety of key processes [4,5,6,7], such as vascular network assembly [8], cartilage formation and sex determination [9,10], neurogenesis [11], as well early stage development and embryonic stem cell pluripotency [12]. SOX proteins within the F group (SOX7, SOX17 and SOX18) reg-
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