The sacral neural crest contributes neurons and glia to the post-umbilical gut: spatiotemporal analysis of the development of the enteric nervous system

Development ◽  
1998 ◽  
Vol 125 (21) ◽  
pp. 4335-4347 ◽  
Author(s):  
A.J. Burns ◽  
N.M. Le Douarin
Keyword(s):  
Nervous System ◽  
Neural Crest ◽  
Enteric Nervous System ◽  
Myenteric Plexus ◽  
Circular Muscle ◽  
Muscle Layer ◽  
Specific Marker ◽  
Circular Muscle Layer ◽  
Sacral Neural Crest ◽  
Antibody Labelling

The majority of the enteric nervous system is derived from vagal neural crest cells (NCC), which migrate to the developing gut, proliferate, form plexuses and differentiate into neurons and glia. However, for some time, controversy has existed as to whether cells from the sacral region of the neural crest also contribute to the enteric nervous system. The aim of this study was to investigate the spatiotemporal migration of vagal and sacral NCC within the developing gut and to determine whether the sacral neural crest contributes neurons and glia to the ENS. We utilised quail-chick chimeric grafting in conjunction with antibody labelling to identify graft-derived cells, neurons and glia. We found that vagal NCC migrated ventrally within the embryo and accumulated in the caudal branchial arches before entering the pharyngeal region and colonising the entire length of the gut in a proximodistal direction. During migration, vagal crest cells followed different pathways depending on the region of the gut being colonised. In the pre-umbilical intestine, NCC were evenly distributed throughout the splanchnopleural mesenchyme while, in the post-umbilical intestine, they occurred adjacent to the serosal epithelium. Behind this migration front, NCC became organised into the presumptive Auerbach's and Meissner's plexuses situated on either side of the developing circular muscle layer. The colorectum was found to be colonised in a complex manner. Vagal NCC initially migrated within the submucosa, internal to the circular muscle layer, before migrating outwards, adjacent to blood vessels, towards the myenteric plexus region. In contrast, sacral NCC, which also formed the entire nerve of Remak, were primarily located in the presumptive myenteric plexus region and subsequently migrated inwards towards the submucosal ganglia. Although present throughout the post-umbilical gut, sacral NCC were most numerous in the distal colorectum where they constituted up to 17% of enteric neurons, as identified by double antibody labelling using the quail-cell-specific marker, QCPN and the neuron-specific marker, ANNA-1. Sacral NCC were also immunopositive for the glial-specific antibody, GFAP, thus demonstrating that this region of the neural crest contributes neurons and glia to the enteric nervous system.

In ovo transplantation of enteric nervous system precursors from vagal to sacral neural crest results in extensive hindgut colonisation

Development ◽  
2002 ◽  
Vol 129 (12) ◽  
pp. 2785-2796 ◽  
Author(s):  
Alan J. Burns ◽  
Jean-Marie M. Delalande ◽  
Nicole M. Le Douarin
Keyword(s):  
Nervous System ◽  
Neural Crest ◽  
Enteric Nervous System ◽  
Enteric Neurons ◽  
In Ovo ◽  
Neuronal Marker ◽  
Sacral Region ◽  
Enteric Ganglia ◽  
Migration Front ◽  
Sacral Neural Crest

The enteric nervous system (ENS) is derived from vagal and sacral neural crest cells (NCC). Within the embryonic avian gut, vagal NCC migrate in a rostrocaudal direction to form the majority of neurons and glia along the entire length of the gastrointestinal tract, whereas sacral NCC migrate in an opposing caudorostral direction, initially forming the nerve of Remak, and contribute a smaller number of ENS cells primarily to the distal hindgut. In this study, we have investigated the ability of vagal NCC, transplanted to the sacral region of the neuraxis, to colonise the chick hindgut and form the ENS in an experimentally generated hypoganglionic hindgut in ovo model. Results showed that when the vagal NC was transplanted into the sacral region of the neuraxis, vagal-derived ENS precursors immediately migrated away from the neural tube along characteristic pathways, with numerous cells colonising the gut mesenchyme by embryonic day (E) 4. By E7, the colorectum was extensively colonised by transplanted vagal NCC and the migration front had advanced caudorostrally to the level of the umbilicus. By E10, the stage at which sacral NCC begin to colonise the hindgut in large numbers, myenteric and submucosal plexuses in the hindgut almost entirely composed of transplanted vagal NCC, while the migration front had progressed into the pre-umbilical intestine, midway between the stomach and umbilicus. Immunohistochemical staining with the pan-neuronal marker, ANNA-1, revealed that the transplanted vagal NCC differentiated into enteric neurons, and whole-mount staining with NADPH-diaphorase showed that myenteric and submucosal ganglia formed interconnecting plexuses, similar to control animals. Furthermore, using an anti-RET antibody, widespread immunostaining was observed throughout the ENS, within a subpopulation of sacral NC-derived ENS precursors, and in the majority of transplanted vagal-to-sacral NCC. Our results demonstrate that: (1) a cell autonomous difference exists between the migration/signalling mechanisms used by sacral and vagal NCC, as transplanted vagal cells migrated along pathways normally followed by sacral cells, but did so in much larger numbers, earlier in development; (2) vagal NCC transplanted into the sacral neuraxis extensively colonised the hindgut, migrated in a caudorostral direction, differentiated into neuronal phenotypes, and formed enteric plexuses; (3) RET immunostaining occurred in vagal crest-derived ENS cells, the nerve of Remak and a subpopulation of sacral NCC within hindgut enteric ganglia.

Analysis of the Sacral Neural Crest Cell Contribution to the Hindgut Enteric Nervous System in the Mouse Embryo

2011 ◽  
Vol 141 (3) ◽  
pp. 992-1002.e6 ◽  
Author(s):  
Xia Wang ◽  
Alex K.K. Chan ◽  
Mai Har Sham ◽  
Alan J. Burns ◽  
Wood Yee Chan
Keyword(s):  
Nervous System ◽  
Neural Crest ◽  
Enteric Nervous System ◽  
Mouse Embryo ◽  
Neural Crest Cell ◽  
Sacral Neural Crest ◽  
Crest Cell

scholarly journals Vital dye labelling demonstrates a sacral neural crest contribution to the enteric nervous system of chick and mouse embryos

Development ◽  
1991 ◽  
Vol 111 (4) ◽  
pp. 857-866 ◽  
Author(s):  
G.N. Serbedzija ◽  
S. Burgan ◽  
S.E. Fraser ◽  
M. Bronner-Fraser
Keyword(s):  
Nervous System ◽  
Neural Crest ◽  
Enteric Nervous System ◽  
Neural Tube ◽  
Neural Crest Cells ◽  
Mouse Embryos ◽  
Chick Embryos ◽  
Vital Dye ◽  
Dorsal Portion ◽  
Sacral Neural Crest

We have used the vital dye, DiI, to analyze the contribution of sacral neural crest cells to the enteric nervous system in chick and mouse embryos. In order to label premigratory sacral neural crest cells selectively, DiI was injected into the lumen of the neural tube at the level of the hindlimb. In chick embryos, DiI injections made prior to stage 19 resulted in labelled cells in the gut, which had emerged from the neural tube adjacent to somites 29–37. In mouse embryos, neural crest cells emigrated from the sacral neural tube between E9 and E9.5. In both chick and mouse embryos, DiI-labelled cells were observed in the rostral half of the somitic sclerotome, around the dorsal aorta, in the mesentery surrounding the gut, as well as within the epithelium of the gut. Mouse embryos, however, contained consistently fewer labelled cells than chick embryos. DiI-labelled cells first were observed in the rostral and dorsal portion of the gut. Paralleling the maturation of the embryo, there was a rostral-to-caudal sequence in which neural crest cells populated the gut at the sacral level. In addition, neural crest cells appeared within the gut in a dorsal-to-ventral sequence, suggesting that the cells entered the gut dorsally and moved progressively ventrally. The present results resolve a long-standing discrepancy in the literature by demonstrating that sacral neural crest cells in both the chick and mouse contribute to the enteric nervous system in the postumbilical gut.

Primary structure, distribution, and effects on motility of CGRP in the intestine of the cod Gadus morhua

1998 ◽  
Vol 275 (1) ◽  
pp. R19-R28 ◽  
Author(s):  
Fatemeh Shahbazi ◽  
Paul Karila ◽  
Catharina Olsson ◽  
Susanne Holmgren ◽  
J. Michael Conlon ◽  
...  
Keyword(s):  
Amino Acid ◽  
Primary Structure ◽  
Myenteric Plexus ◽  
Gadus Morhua ◽  
Circular Muscle ◽  
Muscle Layer ◽  
Inhibitory Response ◽  
Nerve Fibers ◽  
Amino Acid Substitutions ◽  
Circular Muscle Layer

Calcitonin gene-related peptide (CGRP) was isolated from an extract of the intestine of the cod Gadus morhua. The primary structure of this 37-amino acid peptide was established as follows: ACNTA TCVTH RLADF LSRSG GIGNS NFVPT NVGSK AF-NH2. The peptide shows close structural similarities to other nonmammalian (3–4 amino acid substitutions) and mammalian (5–8 amino acid substitutions) CGRPs, and it contains the two residues Asp14 and Phe15 that seem to be characteristic for CGRP in nonmammalian vertebrates. Cod CGRP (10−9–10−7M) inhibited the motility of spontaneously active ring preparations from the cod intestine and was significantly ( P < 0.05) more potent than rat α-CGRP. Neither prostaglandins nor nitric oxide is involved in the inhibitory response produced by cod CGRP, and the lack of effect of tetrodotoxin suggests an action of CGRP on receptors on the intestinal smooth muscle cells. The competitive CGRP antagonist human α-CGRP-(8—37) significantly ( P < 0.05) reduced the response to cod CGRP. Immunohistochemistry demonstrated CGRP-immunoreactive neurons intrinsic to the intestine, and a dense innervation with immunoreactive nerve fibers was observed in the myenteric plexus and the circular muscle layer. Myotomy studies show that CGRP-containing nerves project orally and anally in the myenteric plexus, whereas nerve fibers in the circular muscle layer project mainly anally, indicating a role for CGRP in descending inhibitory pathways of the cod intestine.

Different mechanisms of contraction generation in circular muscle of canine colon

1989 ◽  
Vol 256 (3) ◽  
pp. G570-G580 ◽  
Author(s):  
C. Barajas-Lopez ◽  
J. D. Huizinga
Keyword(s):  
Slow Wave ◽  
Myenteric Plexus ◽  
Calcium Influx ◽  
Direct Action ◽  
Circular Muscle ◽  
Outward Current ◽  
Muscle Layer ◽  
Circular Muscle Layer ◽  
Mechanical Threshold ◽  
In Cells

Smooth muscle cells from the circular muscle layer of the dog colon showed a mechanical threshold of -44 mV. No gradient in mechanical threshold was measured between the cells from the submucosal and myenteric plexus surface. The threshold was passed during the upstroke and the plateau phase of the spontaneous slow-wave activity from cells at the submucosal surface and by spike potentials occurring mainly in cells at the myenteric plexus surface and sporadically in cells at the submucosal surface. Carbachol-induced specific changes in electrical and mechanical activities that were inhibited by calcium influx blockade are as follows: 1) increase in slow-wave duration; 2) decrease in plateau potential; 3) enhancement of spiking activity; and 4) increase in contractility. This indicates that calcium influx is significantly increased in the presence of carbachol in cells at both surfaces of the circular muscle layer. The increase in calcium influx could be the result of a direct action by carbachol on the calcium conductance and/or could be mediated by a decrease in outward current. The latter is suggested by the carbachol-induced membrane depolarization associated with an increase in the input resistance, which were both methoxyverapamil insensitive. The results show that an excitatory stimulus can generate contraction of the circular muscle through different electrophysiological activities. In addition, the patterns of spontaneous electrical activity and the different responses to carbachol stimulation provide further information about the heterogeneous nature of the electrical activities within the colonic circular muscle layer.

scholarly journals Dopamine Transporter Genetic Reduction Induces Morpho-Functional Changes in the Enteric Nervous System

Biomedicines ◽  
2021 ◽  
Vol 9 (5) ◽  
pp. 465
Author(s):  
Silvia Cerantola ◽  
Valentina Caputi ◽  
Gabriella Contarini ◽  
Maddalena Mereu ◽  
Antonella Bertazzo ◽  
...  
Keyword(s):  
Nervous System ◽  
Small Intestine ◽  
Enteric Nervous System ◽  
Dopamine Transporter ◽  
Myenteric Plexus ◽  
Receptor Activation ◽  
D1 Receptor ◽  
Functional Changes ◽  
Neurochemical Coding ◽  
The Impact

Antidopaminergic gastrointestinal prokinetics are indeed commonly used to treat gastrointestinal motility disorders, although the precise role of dopaminergic transmission in the gut is still unclear. Since dopamine transporter (DAT) is involved in several brain disorders by modulating extracellular dopamine in the central nervous system, this study evaluated the impact of DAT genetic reduction on the morpho-functional integrity of mouse small intestine enteric nervous system (ENS). In DAT heterozygous (DAT+/−) and wild-type (DAT+/+) mice (14 ± 2 weeks) alterations in small intestinal contractility were evaluated by isometrical assessment of neuromuscular responses to receptor and non-receptor-mediated stimuli. Changes in ENS integrity were studied by real-time PCR and confocal immunofluorescence microscopy in longitudinal muscle-myenteric plexus whole-mount preparations (). DAT genetic reduction resulted in a significant increase in dopamine-mediated effects, primarily via D1 receptor activation, as well as in reduced cholinergic response, sustained by tachykininergic and glutamatergic neurotransmission via NMDA receptors. These functional anomalies were associated to architectural changes in the neurochemical coding and S100β immunoreactivity in small intestine myenteric plexus. Our study provides evidence that genetic-driven DAT defective activity determines anomalies in ENS architecture and neurochemical coding together with ileal dysmotility, highlighting the involvement of dopaminergic system in gut disorders, often associated to neurological conditions.

Sign in / Sign up

Export Citation Format

Share Document