Nerve-associated Schwann cell precursors contribute extracutaneous melanocytes to the heart, inner ear, supraorbital locations and brain meninges

AbstractMelanocytes are pigmented cells residing mostly in the skin and hair follicles of vertebrates, where they contribute to colouration and protection against UV-B radiation. However, the spectrum of their functions reaches far beyond that. For instance, these pigment-producing cells are found inside the inner ear, where they contribute to the hearing function, and in the heart, where they are involved in the electrical conductivity and support the stiffness of cardiac valves. The embryonic origin of such extracutaneous melanocytes is not clear. We took advantage of lineage-tracing experiments combined with 3D visualizations and gene knockout strategies to address this long-standing question. We revealed that Schwann cell precursors are recruited from the local innervation during embryonic development and give rise to extracutaneous melanocytes in the heart, brain meninges, inner ear, and other locations. In embryos with a knockout of the EdnrB receptor, a condition imitating Waardenburg syndrome, we observed only nerve-associated melanoblasts, which failed to detach from the nerves and to enter the inner ear. Finally, we looked into the evolutionary aspects of extracutaneous melanocytes and found that pigment cells are associated mainly with nerves and blood vessels in amphibians and fish. This new knowledge of the nerve-dependent origin of extracutaneous pigment cells might be directly relevant to the formation of extracutaneous melanoma in humans.

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Schwann cell precursors contribute to skeletal formation during embryonic development in mice and zebrafish

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1900038116 ◽

2019 ◽

Vol 116 (30) ◽

pp. 15068-15073 ◽

Cited By ~ 11

Author(s):

Meng Xie ◽

Dmitrii Kamenev ◽

Marketa Kaucka ◽

Maria Eleni Kastriti ◽

Baoyi Zhou ◽

...

Keyword(s):

Schwann Cell ◽

Embryonic Development ◽

Nerve Fibers ◽

Lineage Tracing ◽

Appendicular Skeleton ◽

Genetic Lineage ◽

Parasympathetic Neurons ◽

Schwann Cell Precursors ◽

Genetic Lineage Tracing ◽

Skeleton Formation

Immature multipotent embryonic peripheral glial cells, the Schwann cell precursors (SCPs), differentiate into melanocytes, parasympathetic neurons, chromaffin cells, and dental mesenchymal populations. Here, genetic lineage tracing revealed that, during murine embryonic development, some SCPs detach from nerve fibers to become mesenchymal cells, which differentiate further into chondrocytes and mature osteocytes. This occurred only during embryonic development, producing numerous craniofacial and trunk skeletal elements, without contributing to development of the appendicular skeleton. Formation of chondrocytes from SCPs also occurred in zebrafish, indicating evolutionary conservation. Our findings reveal multipotency of SCPs, providing a developmental link between the nervous system and skeleton.

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De novo enteric neurogenesis in post-embryonic zebrafish from Schwann cell precursors rather than resident cell types

10.1101/2020.06.01.127712 ◽

2020 ◽

Author(s):

Wael Noor El-Nachef ◽

Marianne E. Bronner

Keyword(s):

Schwann Cell ◽

Normal Development ◽

De Novo ◽

Time Lapse ◽

Cell Types ◽

Lineage Tracing ◽

Enteric Neurons ◽

Embryonic Life ◽

Neuronal Precursors ◽

Schwann Cell Precursors

ABSTRACTThe enteric nervous system is essential for normal gastrointestinal function, but evidence regarding postnatal enteric neurogenesis is conflicting. Using zebrafish as a model, we explored the origin of enteric neurons that arise in post-embryonic life in normal development and injury, and tested effects of the 5-HT4 receptor agonist, prucalopride.To assess enteric neurogenesis, all enteric neurons were photoconverted prior to time-lapse imaging to detect emergence of new neurons. Injury was modeled by two-photon laser ablation of enteric neurons. Lineage tracing was performed with neural tube injections of lipophilic dye and with an inducible Sox10-Cre line. Lastly, we tested prucalopride’s effect on post-embryonic enteric neurogenesis.The post-embryonic zebrafish intestine appears to lack resident neurogenic precursors and enteric glia. However, enteric neurogenesis persists post-embryonically during development and after injury. New enteric neurons arise from trunk neural crest-derived Schwann cell precursors. Prucalopride increases enteric neurogenesis in normal development and after injury if exposure occurs prior to injury.Enteric neurogenesis persists in the post-embryonic period in both normal development and injury, appears to arise from gut-extrinsic Schwann cell precursors, and is promoted by prucalopride.SUMMARY STATEMENTTrunk crest-derived enteric neurogenesis is poorly understood. We find post-embryonic zebrafish lack resident neuronal precursors yet enteric neurogenesis from trunk crest-derived precursors occurs in development, injury, and is promoted by prucalopride.

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Faculty Opinions recommendation of Schwann cell precursors from nerve innervation are a cellular origin of melanocytes in skin.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.1166403.1152065 ◽

2010 ◽

Author(s):

Desmond Tobin

Keyword(s):

Schwann Cell ◽

Cellular Origin ◽

Schwann Cell Precursors

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Schwann cell precursors generate sympathoadrenal system during zebrafish development

Journal of Neuroscience Research ◽

10.1002/jnr.24909 ◽

2021 ◽

Author(s):

Dmitrii Kamenev ◽

Kazunori Sunadome ◽

Maxim Shirokov ◽

Andrey S. Chagin ◽

Ajeet Singh ◽

...

Keyword(s):

Schwann Cell ◽

Sympathoadrenal System ◽

Zebrafish Development ◽

Schwann Cell Precursors

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Schwann cell precursors and their development

Glia ◽

10.1002/glia.440040210 ◽

1991 ◽

Vol 4 (2) ◽

pp. 185-194 ◽

Cited By ~ 175

Author(s):

Kristjan R. Jessen ◽

Rhona Mirsky

Keyword(s):

Schwann Cell ◽

Schwann Cell Precursors

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Developmental Regulation of Schwann Cell Precursors and Schwann Cell Generation

Cell Biology and Pathology of Myelin ◽

10.1007/978-1-4615-5949-8_17 ◽

1997 ◽

pp. 165-172

Author(s):

K. R. Jessen ◽

R. Mirsky ◽

Z. Dong ◽

A. Brennan

Keyword(s):

Schwann Cell ◽

Developmental Regulation ◽

Cell Generation ◽

Schwann Cell Precursors

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Evolution of the hypoxia-sensitive cells involved in amniote respiratory reflexes

eLife ◽

10.7554/elife.21231 ◽

2017 ◽

Vol 6 ◽

Cited By ~ 28

Author(s):

Dorit Hockman ◽

Alan J Burns ◽

Gerhard Schlosser ◽

Keith P Gates ◽

Benjamin Jevans ◽

...

Keyword(s):

Neural Crest ◽

Blood Vessels ◽

Carotid Body ◽

Lineage Tracing ◽

Neuroendocrine Cells ◽

Genetic Lineage ◽

Glomus Cells ◽

Evolutionary Origins ◽

Embryonic Origin ◽

Respiratory Reflexes

The evolutionary origins of the hypoxia-sensitive cells that trigger amniote respiratory reflexes – carotid body glomus cells, and ‘pulmonary neuroendocrine cells’ (PNECs) - are obscure. Homology has been proposed between glomus cells, which are neural crest-derived, and the hypoxia-sensitive ‘neuroepithelial cells’ (NECs) of fish gills, whose embryonic origin is unknown. NECs have also been likened to PNECs, which differentiate in situ within lung airway epithelia. Using genetic lineage-tracing and neural crest-deficient mutants in zebrafish, and physical fate-mapping in frog and lamprey, we find that NECs are not neural crest-derived, but endoderm-derived, like PNECs, whose endodermal origin we confirm. We discover neural crest-derived catecholaminergic cells associated with zebrafish pharyngeal arch blood vessels, and propose a new model for amniote hypoxia-sensitive cell evolution: endoderm-derived NECs were retained as PNECs, while the carotid body evolved via the aggregation of neural crest-derived catecholaminergic (chromaffin) cells already associated with blood vessels in anamniote pharyngeal arches.

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Mutations affecting development of the zebrafish inner ear and lateral line

Development ◽

10.1242/dev.123.1.241 ◽

1996 ◽

Vol 123 (1) ◽

pp. 241-254 ◽

Cited By ~ 33

Author(s):

T.T. Whitfield ◽

M. Granato ◽

F.J. van Eeden ◽

U. Schach ◽

M. Brand ◽

...

Keyword(s):

Inner Ear ◽

Lateral Line ◽

Large Scale ◽

Sensory System ◽

Semicircular Canals ◽

Abnormal Development ◽

Pigment Cells ◽

Otic Vesicle ◽

In The Wild ◽

Complementation Groups

Mutations giving rise to anatomical defects in the inner ear have been isolated in a large scale screen for mutations causing visible abnormalities in the zebrafish embryo (Haffter, P., Granato, M., Brand, M. et al. (1996) Development 123, 1–36). 58 mutants have been classified as having a primary ear phenotype; these fall into several phenotypic classes, affecting presence or size of the otoliths, size and shape of the otic vesicle and formation of the semicircular canals, and define at least 20 complementation groups. Mutations in seven genes cause loss of one or both otoliths, but do not appear to affect development of other structures within the ear. Mutations in seven genes affect morphology and patterning of the inner ear epithelium, including formation of the semicircular canals and, in some, development of sensory patches (maculae and cristae). Within this class, dog-eared mutants show abnormal development of semicircular canals and lack cristae within the ear, while in van gogh, semicircular canals fail to form altogether, resulting in a tiny otic vesicle containing a single sensory patch. Both these mutants show defects in the expression of homeobox genes within the otic vesicle. In a further class of mutants, ear size is affected while patterning appears to be relatively normal; mutations in three genes cause expansion of the otic vesicle, while in little ears and microtic, the ear is abnormally small, but still contains all five sensory patches, as in the wild type. Many of the ear and otolith mutants show an expected behavioural phenotype: embryos fail to balance correctly, and may swim on their sides, upside down, or in circles. Several mutants with similar balance defects have also been isolated that have no obvious structural ear defect, but that may include mutants with vestibular dysfunction of the inner ear (Granato, M., van Eeden, F. J. M., Schach, U. et al. (1996) Development, 123, 399–413,). Mutations in 19 genes causing primary defects in other structures also show an ear defect. In particular, ear phenotypes are often found in conjunction with defects of neural crest derivatives (pigment cells and/or cartilaginous elements of the jaw). At least one mutant, dog-eared, shows defects in both the ear and another placodally derived sensory system, the lateral line, while hypersensitive mutants have additional trunk lateral line organs.

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