Yuta Takase

The dorsal aorta initiates a molecular cascade that instructs sympatho-adrenal specification.

Master Regulator Sympathetic neurons and the adrenal medulla are part of the autonomic nervous system, which is important in the control of a variety of bodily functions and in responses to stress. Interactions between the nervous system and the vascular system have been poorly explored. During development, sympathetic neurons and adrenal medulla cells are derived from the same precursors—neural crest cells—embryonic cohorts that undergo massive migration in the body. Using blood vessel–specific gene manipulation in chicken embryos, Saito et al. (p. 1578) revealed a role for the dorsal aorta in regulating the early migration of neural crest cells and later in development on the segregation of adrenal medulla and sympathetic neurons. The dorsal aorta expresses multiple soluble morphogenetic and growth factors that regulate complex morphogenesis in a spatiotemporal manner. Furthermore, in mice, the morphogenesis of the adrenal medulla was controlled both by the aorta and the adrenal cortex. Morphogenic proteins provided by the dorsal aorta control early and late processes in neurovascular development. The autonomic nervous system, which includes the sympathetic neurons and adrenal medulla, originates from the neural crest. Combining avian blood vessel–specific gene manipulation and mouse genetics, we addressed a long-standing question of how neural crest cells (NCCs) generate sympathetic and medullary lineages during embryogenesis. We found that the dorsal aorta acts as a morphogenetic signaling center that coordinates NCC migration and cell lineage segregation. Bone morphogenetic proteins (BMPs) produced by the dorsal aorta are critical for the production of the chemokine stromal cell–derived factor–1 (SDF -1) and Neuregulin 1 in the para-aortic region, which act as chemoattractants for early migration. Later, BMP signaling is directly involved in the sympatho-medullary segregation. This study provides insights into the complex developmental signaling cascade that instructs one of the earliest events of neurovascular interactions guiding embryonic development.

Low cost labeling with highlighter ink efficiently visualizes developing blood vessels in avian and mouse embryos

To understand how blood vessels form to establish the intricate network during vertebrate development, it is helpful if one can visualize the vasculature in embryos. We here describe a novel labeling method using highlighter ink, easily obtained in stationery stores with a low cost, to visualize embryo‐wide vasculatures in avian and mice. We tested 50 different highlighters for fluorescent microscopy with filter sets equipped in a standard fluorescent microscope. The yellow and violet inks yielded fluorescent signals specifically detected by the filters used for green fluorescent protein (GFP) and red fluorescent protein (RFP) detections, respectively. When the ink solution was infused into chicken/quail and mouse embryos, vasculatures including large vessels and capillaries were labeled both in living and fixed embryos. Ink‐infused embryos were further subjected to histological sections, and double stained with antibodies including QH‐1 (quail), α smooth muscle actin (αSMA), and PECAM‐1 (mouse), revealing that the endothelial cells were specifically labeled by the infused highlighter ink. Highlighter‐labeled signals were detected with a resolution comparable to or higher than signals of fluorescein isothiocyanate (FITC)‐lectin and Rhodamine‐dextran, conventionally used for angiography. Furthermore, macroconfocal microscopic analyses with ink‐infused embryos visualized fine vascular structures of both embryo proper and extra‐embryonic plexus in a Z‐stack image of 2400 μm thick with a markedly high resolution. Together, the low cost highlighter ink serves as an alternative reagent useful for visualization of blood vessels in developing avian and mouse embryos and possibly in other animals.

Angiogenesis in the Developing Spinal Cord: Blood Vessel Exclusion from Neural Progenitor Region Is Mediated by VEGF and Its Antagonists

Blood vessels in the central nervous system supply a considerable amount of oxygen via intricate vascular networks. We studied how the initial vasculature of the spinal cord is formed in avian (chicken and quail) embryos. Vascular formation in the spinal cord starts by the ingression of intra-neural vascular plexus (INVP) from the peri-neural vascular plexus (PNVP) that envelops the neural tube. At the ventral region of the PNVP, the INVP grows dorsally in the neural tube, and we observed that these vessels followed the defined path at the interface between the medially positioned and undifferentiated neural progenitor zone and the laterally positioned differentiated zone. When the interface between these two zones was experimentally displaced, INVP faithfully followed a newly formed interface, suggesting that the growth path of the INVP is determined by surrounding neural cells. The progenitor zone expressed mRNA of vascular endothelial growth factor-A whereas its receptor VEGFR2 and FLT-1 (VEGFR1), a decoy for VEGF, were expressed in INVP. By manipulating the neural tube with either VEGF or the soluble form of FLT-1, we found that INVP grew in a VEGF-dependent manner, where VEGF signals appear to be fine-tuned by counteractions with anti-angiogenic activities including FLT-1 and possibly semaphorins. These results suggest that the stereotypic patterning of early INVP is achieved by interactions between these vessels and their surrounding neural cells, where VEGF and its antagonists play important roles.

Newly raised anti-VAChT and anti-ChAT antibodies detect cholinergic cells in chicken embryos

The autonomic nervous system consists of sympathetic and parasympathetic nerves, which functionally antagonize each other to control physiology and homeostasis of organs. However, it is largely unexplored how the autonomic nervous system is established during development. In particular, early formation of parasympathetic network remains elusive because of its complex anatomical structure. To distinguish between parasympathetic (cholinergic) and sympathetic (adrenergic) ganglia, vesicular acetylcholine transporter (VAChT) and choline O‐acetyltransferase (ChAT), proteins associated with acetylcholine synthesis, are known to be useful markers. Whereas commercially available antibodies against these proteins are widely used for mammalian specimens including mice and rats, these antibodies do not work satisfactorily in chickens, although chicken is an excellent model for the study of autonomic nervous system. Here, we newly raised antibodies against chicken VAChT and ChAT proteins. One monoclonal and three polyclonal antibodies for VAChT, and one polyclonal antibody for ChAT were obtained, which were available for Western blotting analyses and immunohistochemistry. Using these verified antibodies, we detected cholinergic cells in Remak ganglia of autonomic nervous system, which form in the dorsal aspect of the digestive tract of chicken E13 embryos. The antibodies obtained in this study are useful for visualization of cholinergic neurons including parasympathetic ganglia.

Blood flow-mediated gene transfer and siRNA-knockdown in the developing vasculature in a spatio-temporally controlled manner in chicken embryos

We describe a method by which early developing vasculature can be gene-manipulated independently of the heart in a spatio-temporally controlled manner. Lipofectamine 2000 or 3000, an easy-to-use lipid reagent, has been found to yield a high efficiency of transfection when co-injected with GFP DNA within a critical range of lipid concentration. By exploiting developmentally changing patterns of vasculature and blood flow, we have succeed in controlling the site of transfection: injection with a lipid-DNA cocktail into the heart before or after the blood circulation starts results in a limited and widely spread patterns of transfection, respectively. Furthermore, a cocktail injection into the right dorsal aorta leads to transgenesis of the right half of embryonic vasculature. In addition, this method combined with the siRNA technique has allowed, for the first time, to knockdown the endogenous expression of VE-cadherin (also called Cdh5), which has been implicated in assembly of nasant blood vessels: when Cah5 siRNA is injected into the right dorsal aorta, pronounced defects in the right half of vasculature are observed without heart defects. Whereas infusion-mediated gene transfection method has previously been reported using lipid reagents that were elaborately prepared on their own, Lipofectamine is an easy-use reagent with no requirement of special expertise. The methods reported here would overcome shortcomings of conventional vascular-transgenic animals, such as mice and zebrafish, in which pan-endothelial enhancer-driven transgenesis often leads to the heart malformation, which, in turn, indirectly affects peripheral vasculature due to flow defects. Since a variety of subtypes in vasculature have increasingly been appreciated, the spatio-temporally controllable gene manipulation described in this study offers a powerful tool. Research Highlights Blood flow-mediated transfection enables site-specific transgenesis in vessels. This transfection technique allows local knockdown of endogenous gene(s) by siRNA. Knockdown of endogenous VE-cadherin causes vascular defects without heart failure.

Comparison of the 3-D patterns of the parasympathetic nervous system in the lung at late developmental stages between mouse and chicken

Although the basic schema of the body plan is similar among different species of amniotes (mammals, birds, and reptiles), the lung is an exception. Here, anatomy and physiology are considerably different, particularly between mammals and birds. In mammals, inhaled and exhaled airs mix in the airways, whereas in birds the inspired air flows unidirectionally without mixing with the expired air. This bird-specific respiration system is enabled by the complex tubular structures called parabronchi where gas exchange takes place, and also by the bellow-like air sacs appended to the main part of the lung. That the lung is predominantly governed by the parasympathetic nervous system has been shown mostly by physiological studies in mammals. However, how the parasympathetic nervous system in the lung is established during late development has largely been unexplored both in mammals and birds. In this study, by combining immunocytochemistry, the tissue-clearing CUBIC method, and ink-injection to airways, we have visualized the 3-D distribution patterns of parasympathetic nerves and ganglia in the lung at late developmental stages of mice and chickens. These patterns were further compared between these species, and three prominent similarities emerged: (1) parasympathetic postganglionic fibers and ganglia are widely distributed in the lung covering the proximal and distal portions, (2) the gas exchange units, alveoli in mice and parabronchi in chickens, are devoid of parasympathetic nerves, (3) parasympathetic nerves are in close association with smooth muscle cells, particularly at the base of the gas exchange units. These observations suggest that despite gross differences in anatomy, the basic mechanisms underlying parasympathetic control of smooth muscles and gas exchange might be conserved between mammals and birds.