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01-04-2016 | Original Paper

In vitro modeling of endothelial interaction with macrophages and pericytes demonstrates Notch signaling function in the vascular microenvironment

Authors: Ian W. Tattersall, Jing Du, Zhuangzhuang Cong, Bennet S. Cho, Alyssa M. Klein, Chelsea L. Dieck, Reyhaan A. Chaudhri, Henar Cuervo, James H. Herts, Jan Kitajewski

Published in: Angiogenesis | Issue 2/2016

Abstract

Angiogenesis is regulated by complex interactions between endothelial cells and support cells of the vascular microenvironment, such as tissue myeloid cells and vascular mural cells. Multicellular interactions during angiogenesis are difficult to study in animals and challenging in a reductive setting. We incorporated stromal cells into an established bead-based capillary sprouting assay to develop assays that faithfully reproduce major steps of vessel sprouting and maturation. We observed that macrophages enhance angiogenesis, increasing the number and length of endothelial sprouts, a property we have dubbed “angiotrophism.” We found that polarizing macrophages toward a pro-inflammatory profile further increased their angiotrophic stimulation of vessel sprouting, and this increase was dependent on macrophage Notch signaling. To study endothelial/pericyte interactions, we added vascular pericytes directly to the bead-bound endothelial monolayer. These pericytes formed close associations with the endothelial sprouts, causing increased sprout number and vessel caliber. We found that Jagged1 expression and Notch signaling are essential for the growth of both endothelial cells and pericytes and may function in their interaction. We observed that combining endothelial cells with both macrophages and pericytes in the same sprouting assay has multiplicative effects on sprouting. These results significantly improve bead-capillary sprouting assays and provide an enhanced method for modeling interactions between the endothelium and the vascular microenvironment. Achieving this in a reductive in vitro setting represents a significant step toward a better understanding of the cellular elements that contribute to the formation of mature vasculature.

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Title: In vitro modeling of endothelial interaction with macrophages and pericytes demonstrates Notch signaling function in the vascular microenvironment
Authors: Ian W. Tattersall
Jing Du
Zhuangzhuang Cong
Bennet S. Cho
Alyssa M. Klein
Chelsea L. Dieck
Reyhaan A. Chaudhri
Henar Cuervo
James H. Herts
Jan Kitajewski
Publication date: 01-04-2016
Publisher: Springer Netherlands
Published in: Angiogenesis / Issue 2/2016
Print ISSN: 0969-6970
Electronic ISSN: 1573-7209
DOI: https://doi.org/10.1007/s10456-016-9501-1

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