Shane P. Herbert scite author profile

The vertebrate vasculature forms an extensive branched network of blood vessels that supplies tissues with nutrients and oxygen. During vascular development, coordinated control of endothelial cell behaviour at the levels of cell migration, proliferation, polarity, differentiation and cell–cell communication is critical for functional blood vessel morphogenesis. Recent data uncover elaborate transcriptional, post-transcriptional and post-translational mechanisms that fine-tune key signalling pathways (such as the vascular endothelial growth factor and Notch pathways) to control endothelial cell behaviour during blood vessel sprouting (angiogenesis). These emerging frameworks controlling angiogenesis provide unique insights into fundamental biological processes common to other systems, such as tissue branching morphogenesis, mechanotransduction and tubulogenesis.

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Arterial-Venous Segregation by Selective Cell Sprouting: An Alternative Mode of Blood Vessel Formation

Herbert

Huisken

Kim

et al. 2009

Science

307

258

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Blood vessels form de novo (vasculogenesis) or upon sprouting of capillaries from pre-existing vessels (angiogenesis). Using high resolution imaging of zebrafish vascular development we discovered a third mode of blood vessel formation whereby the first embryonic artery and vein, two unconnected blood vessels, arise from a common precursor vessel. The first embryonic vein formed by selective sprouting of progenitor cells from the precursor vessel, followed by vessel segregation. These processes were regulated by the ligand EphrinB2 and its receptor EphB4, which are expressed in arterial-fated and venous-fated progenitors, respectively, and interact to orient the direction of progenitor migration. Thus, directional control of progenitor migration drives arterial/venous segregation and generation of separate parallel vessels from a single precursor vessel, a process essential for vascular development.

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Ligand‐Stimulated VEGFR2 Signaling is Regulated by Co‐Ordinated Trafficking and Proteolysis

Bruns

Herbert

Odell

et al. 2009

Traffic

127

195

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Vascular endothelial growth factor A (VEGF-A)-induced signaling through VEGF receptor 2 (VEGFR2) regu-lates both physiological and pathological angiogenesis in mammals. However, the temporal and spatial mechanism underlying VEGFR2-mediated intracellular signaling is not clear. Here, we define a pathway for VEGFR2 trafficking and proteolysis that regulates VEGF-A-stimulated signaling and endothelial cell migration. Ligand-stimulated VEGFR2 activation and ubiquitination preceded proteolysis and cytoplasmic domain removal associated with endosomes. A soluble VEGFR2 cytoplasmic domain fragment displayed tyrosine phosphorylation and activation of downstream intracellular signaling. Perturbation of endocytosis by the depletion of either clathrin heavy chain or an ESCRT-0 subunit caused differential effects on ligand-stimulated VEGFR2 proteolysis and signaling. This novel VEGFR2 proteolysis was blocked by the inhibitors of 26S proteasome activity. Inhibition of proteasome activity prolonged VEGF-A-induced intracellular signaling to c-Akt and endothelial nitric oxide synthase (eNOS). VEGF-A-stimulated endothelial cell migration was dependent on VEGFR2 and VEGFR tyrosine kinase activity. Inhibition of proteasome activity in this assay stimulated VEGF-A-mediated endothelial cell migration. VEGFR2 endocytosis, ubiquitination and proteolysis could also be stimulated by a protein kinase C-dependent pathway. Thus, removal of the VEGFR2 carboxyl terminus linked to phosphorylation, ubiquitination and trafficking is necessary for VEGF-stimulated endothelial signaling and cell migration.

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Asymmetric division coordinates collective cell migration in angiogenesis

et al. 2016

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The asymmetric division of stem or progenitor cells generates daughters with distinct fates and regulates cell diversity during tissue morphogenesis. However, roles for asymmetric division in other more dynamic morphogenetic processes, such as cell migration, have not previously been described. Here we combine zebrafish in vivo experimental and computational approaches to reveal that heterogeneity introduced by asymmetric division generates multicellular polarity that drives coordinated collective cell migration in angiogenesis. We find that asymmetric positioning of the mitotic spindle during endothelial tip cell division generates daughters of distinct size with discrete “tip” or “stalk” thresholds of pro-migratory Vegfr signalling. Consequently, post-mitotic Vegfr asymmetry drives Dll4/Notch-independent self-organisation of daughters into leading tip or trailing stalk cells, and disruption of asymmetry randomises daughter tip/stalk selection. Thus, asymmetric division seamlessly integrates cell proliferation with collective migration, and as such, may facilitate growth of other collectively migrating tissues during development, regeneration and cancer invasion.

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Shane P. Herbert

Molecular control of endothelial cell behaviour during blood vessel morphogenesis

Arterial-Venous Segregation by Selective Cell Sprouting: An Alternative Mode of Blood Vessel Formation

Ligand‐Stimulated VEGFR2 Signaling is Regulated by Co‐Ordinated Trafficking and Proteolysis

Asymmetric division coordinates collective cell migration in angiogenesis

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