Endothelial cell self-fusion during vascular pruning.

Anna Lenard,Charles Betz,Elin Ellertsdottir,Stephan Daetwyler,Jan Huisken,Markus Affolter,Heinz-Georg Belting,Brigid L M Hogan

doi:10.1371/journal.pbio.1002126

Anna Lenard, Charles Betz + Show 6 more

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https://doi.org/10.1371/journal.pbio.1002126

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Abstract

During embryonic development, vascular networks remodel to meet the increasing demand of growing tissues for oxygen and nutrients. This is achieved by the pruning of redundant blood vessel segments, which then allows more efficient blood flow patterns. Because of the lack of an in vivo system suitable for high-resolution live imaging, the dynamics of the pruning process have not been described in detail. Here, we present the subintestinal vein (SIV) plexus of the zebrafish embryo as a novel model to study pruning at the cellular level. We show that blood vessel regression is a coordinated process of cell rearrangements involving lumen collapse and cell–cell contact resolution. Interestingly, the cellular rearrangements during pruning resemble endothelial cell behavior during vessel fusion in a reversed order. In pruning segments, endothelial cells first migrate toward opposing sides where they join the parental vascular branches, thus remodeling the multicellular segment into a unicellular connection. Often, the lumen is maintained throughout this process, and transient unicellular tubes form through cell self-fusion. In a second step, the unicellular connection is resolved unilaterally, and the pruning cell rejoins the opposing branch. Thus, we show for the first time that various cellular activities are coordinated to achieve blood vessel pruning and define two different morphogenetic pathways, which are selected by the flow environment.

Highlights

The vascular system of vertebrates distributes oxygen, nutrients, metabolites, and blood cells to and from all organs of the body
The blood vasculature circulates gas, nutrients, hormones, and metabolites to all organs of the body. It is indispensable for survival and already functions at very early stages of embryonic development
Our in vivo live imaging studies of the pruning process in the zebrafish embryo show that vessel regression occurs through cell rearrangements, wherein cells consecutively migrate out of the pruning branch

Summary

Introduction

The vascular system of vertebrates distributes oxygen, nutrients, metabolites, and blood cells to and from all organs of the body. As the demand for oxygen and nutrients during organ or embryonic growth increases, these primitive networks become remodeled to allow more efficient blood transport Such vascular remodeling involves changes in vessel diameter as well as pruning of supernumerary vascular branches [4]. Taking advantage of the ease of performing live imaging in the zebrafish embryo, the latter studies showed that regression of vessels occurs through endothelial cell rearrangements typically in the absence of apoptosis. These studies showed that pruning is regulated by hemodynamic forces, since blood vessel regression was preceded by changes in blood flow patterns due to rewiring of the vascular plexus

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