Origin, prospective identification, and function of circulating endothelial colony-forming cells in mice and humans
Yang Lin, Kimihiko Banno, Chang-Hyun Gil, Jered Myslinski, Takashi Hato, William C. Shelley, Hongyu Gao, Xiaoling Xuei, Yunlong Liu, David P. Basile, Momoko Yoshimoto, Nutan Prasain, Stefan P. Tarnawsky, Ralf H. Adams, Katsuhiko Naruse, Junko Yoshida, Michael P. Murphy, Kyoji Horie, Mervin C. Yoder
Yang Lin, Kimihiko Banno, Chang-Hyun Gil, Jered Myslinski, Takashi Hato, William C. Shelley, Hongyu Gao, Xiaoling Xuei, Yunlong Liu, David P. Basile, Momoko Yoshimoto, Nutan Prasain, Stefan P. Tarnawsky, Ralf H. Adams, Katsuhiko Naruse, Junko Yoshida, Michael P. Murphy, Kyoji Horie, Mervin C. Yoder
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Research Article Vascular biology

Origin, prospective identification, and function of circulating endothelial colony-forming cells in mice and humans

Abstract

Most circulating endothelial cells are apoptotic, but rare circulating endothelial colony-forming cells (C-ECFCs), also known as blood outgrowth endothelial cells, with proliferative and vasculogenic activity can be cultured; however, the origin and naive function of these C-ECFCs remains obscure. Herein, detailed lineage tracing revealed murine C-ECFCs emerged in the early postnatal period, displayed high vasculogenic potential with enriched frequency of clonal proliferative cells compared with tissue-resident ECFCs, and were not committed to or derived from the BM hematopoietic system but from tissue-resident ECFCs. In humans, C-ECFCs were present in the CD34bright cord blood mononuclear subset, possessed proliferative potential and in vivo vasculogenic function in a naive or cultured state, and displayed a single cell transcriptome sharing some umbilical venous endothelial cell features, such as a higher protein C receptor and extracellular matrix gene expression. This study provides an advance for the field by identifying the origin, naive function, and antigens to prospectively isolate C-ECFCs for translational studies.

Authors

Yang Lin, Kimihiko Banno, Chang-Hyun Gil, Jered Myslinski, Takashi Hato, William C. Shelley, Hongyu Gao, Xiaoling Xuei, Yunlong Liu, David P. Basile, Momoko Yoshimoto, Nutan Prasain, Stefan P. Tarnawsky, Ralf H. Adams, Katsuhiko Naruse, Junko Yoshida, Michael P. Murphy, Kyoji Horie, Mervin C. Yoder

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Figure 2

Abundance of murine C-ECFCs with clonal proliferative potential and their vessel-forming capacities with and without prior culture, comparable to human C-ECFCs.

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Abundance of murine C-ECFCs with clonal proliferative potential and thei...
(A) Schematic of single-cell colony-forming assay using CD45Ter119CD31+TT+ cells in Tie2TT mice (P2). Right panel shows a representative picture of an EC colony. TT+ EC colonies were confirmed at least 4 times. (B) Quantitation of the frequency of ECFCs from PB, lung, or heart-derived CD45Ter119CD31+TT+ cells in Tie2CreTT mice (P2). n = 3–4. Data are shown as the mean ± SD. **P < 0.01. Tukey-Kramer post hoc test. (C) Uncultured and cultured human CB CD34+CD45 cells (MACS sorted) can form functional blood vessels in vivo after transplantation; 4 successes out of 4 recipients of uncultured cells. (D) Representative TT+ vessel of uncultured and cultured Tie2TT PB injection to hind limb muscle; 2 successes out of 4 recipients of uncultured cells. Scale bars: 200 μm (C), 50 μm (D).