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Dll4 assembles the umbilical cord and placental vasculature
Derek C. Sung, Hana A. Ahanger, Sweta Narayan, Jesse A. Pace, Mei Chen, Jisheng Yang, Siqi Gao, T.C.S. Keller IV, Jenna Bockman, Xiaowen Chen, Erica Nguyen, Alan T. Tang, Patricia Mericko-Ishizuka, Ivan Maillard, Mark L. Kahn
Derek C. Sung, Hana A. Ahanger, Sweta Narayan, Jesse A. Pace, Mei Chen, Jisheng Yang, Siqi Gao, T.C.S. Keller IV, Jenna Bockman, Xiaowen Chen, Erica Nguyen, Alan T. Tang, Patricia Mericko-Ishizuka, Ivan Maillard, Mark L. Kahn
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Research Article Development Reproductive biology Vascular biology

Dll4 assembles the umbilical cord and placental vasculature

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Abstract

Proper development of the umbilical cord and placental vasculature is essential for embryonic development. While the allantois is known give rise to endothelial cells (ECs) within the placenta, whether the allantois gives rise to ECs in the umbilical cord is debated. Furthermore, a lack of genetic tools to study placental vascular development independent of the embryo proper has hindered robust investigation into the primary cause of vascular defects from early studies utilizing global KOs. In this study, we delineate the contribution of the allantois to the umbilical vessels and utilize a mouse genetic tool previously developed by our lab to revisit the role of Notch signaling during placental development. We show that the allantois has mosaic contribution to the umbilical endothelium with higher contributions closer to the placenta. Allantoic deletion of Dll4 disrupts umbilical cord and placental vascular formation with secondary defects in the heart. Lastly, we identify Unc5b downstream of Notch signaling that restricts EC migration while promoting chemokine signaling for vascular smooth muscle cell (vSMC) recruitment to arteries. These findings identify a genetic tool for investigating placental vascular development and give insights into the ontogeny and mechanisms of placental vascular and umbilical cord development.

Authors

Derek C. Sung, Hana A. Ahanger, Sweta Narayan, Jesse A. Pace, Mei Chen, Jisheng Yang, Siqi Gao, T.C.S. Keller IV, Jenna Bockman, Xiaowen Chen, Erica Nguyen, Alan T. Tang, Patricia Mericko-Ishizuka, Ivan Maillard, Mark L. Kahn

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Figure 2

Dll4 is expressed in umbilical and placental arteries and required for embryonic survival.

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Dll4 is expressed in umbilical and placental arteries and required for ...
(A) Immunofluorescence staining and RNA-FISH of E9.0 placenta for CK8 (green), TIE2 (red), and Dll4 (gray, RNA). Scale bars: 100 μm. (B–D) Immunofluorescence staining and RNA-FISH of E10.5 umbilical cord (B) and placenta (C and D) for CK8 (green), TIE2 (red), and Dll4 (gray, RNA). White arrowheads point to Dll4+ endothelial cells near the labyrinth-junctional zone border (dashed line). UA, umbilical artery; UV, umbilical vein; A, artery; V, vein. Scale bars: 50 μm. (E–G) Gross images of control and Hoxa13Cre;Dll4fl/fl embryos and placentas at E9.5 (E), E10.5 (F), and E11.5 (G). Yellow arrowhead points to vascular congestion. White arrowhead points to pericardial edema. (H and I) Immunofluorescence staining of E10.5 control and Hoxa13Cre;Dll4fl/fl embryos for αSMA (green), CD31 (red), and Ki67 (magenta). Red arrows point to Ki67+ regions in the neural tube (NT). White arrows point to αSMA+ surrounding the dorsal aorta. Yellow arrows point to Ki67+ cardiomyocytes. Scale bars: 100 μm. (J and K) Quantification of dorsal aorta lumen area and perivascular αSMA+ smooth muscle cells (n = 5–6 embryos per genotype). Data represent mean ± SD. An unpaired t test was performed for statistical analysis.

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