Abstract
The formation of the central nervous system (CNS) involves multiple cellular and molecular interactions between neural progenitor cells (NPCs) and blood vessels to establish extensive and complex neural networks and attract a vascular supply that support their function. In this review, we discuss studies that have performed genetic manipulations of chick, fish and mouse embryos to define the spatiotemporal roles of molecules that mediate the reciprocal regulation of NPCs and blood vessels. These experiments have highlighted core functions of NPC-expressed ligands in initiating vascular growth into and within the neural tube as well as establishing the blood–brain barrier. More recent findings have also revealed indispensable roles of blood vessels in regulating NPC expansion and eventual differentiation, and specific regional differences in the effect of angiocrine signals. Accordingly, NPCs initially stimulate blood vessel growth and maturation to nourish the brain, but blood vessels subsequently also regulate NPC behaviour to promote the formation of a sufficient number and diversity of neural cells. A greater understanding of the molecular cross-talk between NPCs and blood vessels will improve our knowledge of how the vertebrate nervous system forms and likely help in the design of novel therapies aimed at regenerating neurons and neural vasculature following CNS disease or injury.
Highlights
The formation of the central nervous system (CNS) begins early in development following the specification of the ectodermal germ layer [1]
The neural ectoderm develops into the neuroepithelium, which is initially comprised of a small pool of highly proliferative neural progenitor cells (NPCs) that will give rise to all glia and neurons in the adult nervous system via several NPC-derived lineages [2]
SFLT1 expression in the zebrafish neural tube, regulated non-cell autonomously by resident radial glia, restricts Vascular endothelial growth factor (VEGF)-induced radial vessel ingression into the spinal cord to specific sites and limits oversprouting within the parenchyma, demonstrating that endogenous flt1 expression is essential for normal CNS vascularisation [11,52]
Summary
The formation of the central nervous system (CNS) begins early in development following the specification of the ectodermal germ layer [1]. Both the number of endothelial filopodia and filopodial length, and vessel branching and vascular coverage, are decreased in the cortex of mouse embryos with reduced, but not absent Vegfa expression, demonstrating that brain angiogenesis is regulated by VEGF-A in a dose-dependent manner [16] (Figure 2 A).
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