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  2. The role of Hath6, a newly identified shear-stress-responsive transcription factor, in endothelial cell differentiation and function

The role of Hath6, a newly identified shear-stress-responsive transcription factor, in endothelial cell differentiation and function

  • J Cell Sci. 2014 Apr 1;127(Pt 7):1428-40. doi: 10.1242/jcs.136358.
Fang Fang 1 Scott M Wasserman Jesus Torres-Vazquez Brant Weinstein Feng Cao Zongjin Li Kitchener D Wilson Wen Yue Joseph C Wu Xiaoyan Xie Xuetao Pei
Affiliations

Affiliation

  • 1 Stem Cells and Regenerative Medicine Lab, Beijing Institute of Transfusion Medicine, Beijing, China.
Abstract

The key regulators of endothelial differentiation that is induced by shear stress are mostly unclear. Human atonal homolog 6 (Hath6 or ATOH8) is an endothelial-selective and shear-stress-responsive transcription factor. In this study, we sought to elucidate the role of Hath6 in the endothelial specification of embryonic stem cells. In a stepwise human embryonic stem cell to endothelial cell (hESC-EC) induction system, Hath6 mRNA was upregulated synchronously with endothelial determination. Subsequently, gain-of-function and loss-of-function studies of Hath6 were performed using the hESC-EC induction model and endothelial cell lines. The overexpression of Hath6, which mimics shear stress treatment, resulted in an increased CD45(-)CD31(+)VEGFR2/KDR/Flk-1(+) population, a higher tubular-structure-formation capacity and increased endothelial-specific gene expression. By contrast, the knockdown of Hath6 mRNA markedly decreased endothelial differentiation. Hath6 also facilitated the maturation of endothelial cells in terms of endothelial gene expression, tubular-structure formation and cell migration. We further demonstrated that the gene encoding eNOS is a direct target of Hath6 through a reporter system assay and western blot analysis, and that the inhibition of eNOS diminishes hESC-EC differentiation. These results suggest that eNOS plays a key role in linking Hath6 to the endothelial phenotype. Further in situ hybridization studies in zebrafish and mouse embryos indicated that homologs of Hath6 are involved in vasculogenesis and angiogenesis. This study provides the first confirmation of the positive impact of Hath6 on human embryonic endothelial differentiation and function. Moreover, we present a potential signaling pathway through which shear stress stimulates endothelial differentiation.

Keywords

Endothelial differentiation; Hath6; Human embryonic stem cells.

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