Mesenteric Neural Crest Cells Are the Embryological Basis of Skip Segment Hirschsprung's Disease

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TitreMesenteric Neural Crest Cells Are the Embryological Basis of Skip Segment Hirschsprung's Disease
Type de publicationJournal Article
Year of Publication2021
AuteursYu Q, Du M, Zhang W, Liu L, Gao Z, Chen W, Gu Y, Zhu K, Niu X, Sun Q, Wang L
JournalCELLULAR AND MOLECULAR GASTROENTEROLOGY AND HEPATOLOGY
Volume12
Pagination1-24
Type of ArticleArticle
ISSN2352-345X
Mots-clésAganglionosis, EDN3/EDNRB Signaling Pathway, Enteric Nervous System, gastrointestinal tract
Résumé

BACKGROUND & AIMS: Defective rostrocaudal colonization of the gut by vagal neural crest cells (vNCCs) results in Hirschsprung's disease (HSCR), which is characterized by aganglionosis in variable lengths of the distal bowel. Skip segment Hirschsprung's disease (SSHD), referring to a ganglionated segment within an otherwise aganglionic intestine, contradicts HSCR pathogenesis and underscores a significant gap in our understanding of the development of the enteric nervous system. Here, we aimed to identify the embryonic origin of the ganglionic segments in SSHD. METHODS: Intestinal biopsy specimens from HSCR patients were prepared via the Swiss-roll technique to search for SSHD cases. NCC migration from the neural tube to the gut was spatiotemporally traced using targeted cell lineages and gene manipulation in mice. RESULTS: After invading the mesentery surrounding the foregut, vNCCs separated into 2 populations: mesenteric NCCs (mNCCs) proceeded to migrate along the mesentery, whereas enteric NCCs invaded the foregut to migrate along the gut. mNCCs not only produced neurons and glia within the gut mesentery, but also continuously complemented the enteric NCC pool. Two new cases of SSHD were identified from 183 HSCR patients, and Ednrb-mutant mice, but not Ret(-/-) mice, showed a high incidence rate of SSHD-like phenotypes. CONCLUSIONS: mNCCs, a subset of vNCCs that migrate into the gut via the gut mesentery to give rise to enteric neurons, could provide an embryologic explanation for SSHD. These findings lead to novel insights into the development of the enteric nervous system and the etiology of HSCR.

DOI10.1016/j.jcmgh.2020.12.010