Endothelium and NOTCH specify and amplify aorta-gonad-mesonephros–derived hematopoietic stem cells
Brandon K. Hadland, … , Shahin Rafii, Irwin D. Bernstein
Brandon K. Hadland, … , Shahin Rafii, Irwin D. Bernstein
Published April 13, 2015
Citation Information: J Clin Invest. 2015;125(5):2032-2045. https://doi.org/10.1172/JCI80137.
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Research Article Hematology

Endothelium and NOTCH specify and amplify aorta-gonad-mesonephros–derived hematopoietic stem cells

Abstract

Hematopoietic stem cells (HSCs) first emerge during embryonic development within vessels such as the dorsal aorta of the aorta-gonad-mesonephros (AGM) region, suggesting that signals from the vascular microenvironment are critical for HSC development. Here, we demonstrated that AGM-derived endothelial cells (ECs) engineered to constitutively express AKT (AGM AKT-ECs) can provide an in vitro niche that recapitulates embryonic HSC specification and amplification. Specifically, nonengrafting embryonic precursors, including the VE-cadherin–expressing population that lacks hematopoietic surface markers, cocultured with AGM AKT-ECs specified into long-term, adult-engrafting HSCs, establishing that a vascular niche is sufficient to induce the endothelial-to-HSC transition in vitro. Subsequent to hematopoietic induction, coculture with AGM AKT-ECs also substantially increased the numbers of HSCs derived from VE-cadherin+CD45+ AGM hematopoietic cells, consistent with a role in supporting further HSC maturation and self-renewal. We also identified conditions that included NOTCH activation with an immobilized NOTCH ligand that were sufficient to amplify AGM-derived HSCs following their specification in the absence of AGM AKT-ECs. Together, these studies begin to define the critical niche components and resident signals required for HSC induction and self-renewal ex vivo, and thus provide insight for development of defined in vitro systems targeted toward HSC generation for therapeutic applications.

Authors

Brandon K. Hadland, Barbara Varnum-Finney, Michael G. Poulos, Randall T. Moon, Jason M. Butler, Shahin Rafii, Irwin D. Bernstein

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Figure 4

Coculture on AGM AKT-ECs increases long-term HSCs from E11 AGM CD45+VE-cadherin+ cells.

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Coculture on AGM AKT-ECs increases long-term HSCs from E11 AGM CD45+VE-c...
(A) Schematic of coculture experiments. Dotted box indicates approximate region of the AGM. (B) Surface phenotyping for LSK and LSK-SLAM subset (CD48CD150+), designated by red boxes, of cells cultured on AGM AKT-ECs or control (no EC). (C) Total CD45+, myeloid (Gr1+ and/or F4/80+), LSK, and LSK-SLAM cells generated per embryo equivalent (ee) of starting cells. (*P < 0.001, **P < 0.01, AGM AKT-EC vs. no EC, unpaired Student’s t test ). Shown is mean ± SD from replicate samples (n = 3), from representative experiment (n = 3). (D) Engraftment following transplantation of E11 CD45+VE-cadherin+ cells cultured on AGM AKT-ECs or control (no EC). Shown at each time point is mean ± SD of donor PB engraftment (n = 3 experiments, 12 total mice), transplanted at 1 ee. (E) Donor-derived PB engraftment at ≥16 weeks from n = 7 primary recipients (transplanted with AGM AKT-cultured cells) transplanted to each of 2 secondary recipients. (F) Engraftment in PB at ≥16 weeks after transplant from control (uncultured) cells transplanted at 1 ee, OP9-cultured cells transplanted at 0.1 ee, or cells cultured on multiple independent AGM AKT-ECs (#1-3) transplanted with dilutions of cultured cells expressed per ee of starting population. Numbers above indicate fraction of mice with multilineage engraftment, designated by data points in red. Limit-dilution analysis of HSC/RU (repopulating units) generated following culture on AGM AKT-ECs (#3) by ELDA analysis (60). Dotted lines represent 95% confidence interval (216-2268 HSC/RU per ee).