Annette J. Bergner

Acquisition of neuronal and glial markers by neural crest–derived cells in the mouse intestine

Enteric neurons and glia arise from the neural crest. The phenotype of crest‐derived cells was examined as they differentiated into neurons or glia in the mouse small and large intestine. Previous studies have shown that undifferentiated enteric crest–derived cells are Phox2b+/Ret+/p75+/Sox10+, and at embryonic day (E) 10.5, about 10–15% of the crest‐derived cells in the small intestine have started to differentiate into neurons. In the current study, by E12.5 and E14.5, about 25% and 47%, respectively, of Phox2b+ cells in the small intestine were immunoreactive to the pan‐neuronal protein, ubitquitin hydrolase (PGP9.5), and the percentage did not change dramatically from E14.5 onward. The differentiation of crest‐derived cells into neurons in the colon lagged behind that in the small intestine by several days. Differentiating enteric neurons showed high Ret, low p75, and undetectable Sox10 immunostaining. Glial precursors were identified by the presence of brain‐specific fatty acid binding protein (B‐FABP) and detected first in the fore‐ and rostral midgut at E11.5. Glial precursors appeared to be B‐FABP+/Sox10+/p75+ but showed low Ret immunostaining. S100b was not detected until E14.5. Adult glial cells were B‐FABP+/Sox10+/p75+/S100b+. A nucleic acid stain (to identify all ganglion cells) was combined with immunostaining for PGP9.5 and S100b to detect neurons and glial cells, respectively, in the postnatal intestine. At postnatal day 0, fewer than 5% and 10% of cells in myenteric ganglia of the small and large intestine, respectively, were neither PGP9.5+ nor S100b+. Because some classes of neurons are not present in significant numbers until after birth, the expression of PGP9.5 by developing enteric neurons appeared to precede the expression of neuron type–specific markers. J. Comp. Neurol. 456:1–11, 2003.

Transplanted progenitors generate functional enteric neurons in the postnatal colon

Cell therapy has the potential to treat gastrointestinal motility disorders caused by diseases of the enteric nervous system. Many studies have demonstrated that various stem/progenitor cells can give rise to functional neurons in the embryonic gut; however, it is not yet known whether transplanted neural progenitor cells can migrate, proliferate, and generate functional neurons in the postnatal bowel in vivo. We transplanted neurospheres generated from fetal and postnatal intestinal neural crest-derived cells into the colon of postnatal mice. The neurosphere-derived cells migrated, proliferated, and generated neurons and glial cells that formed ganglion-like clusters within the recipient colon. Graft-derived neurons exhibited morphological, neurochemical, and electrophysiological characteristics similar to those of enteric neurons; they received synaptic inputs; and their neurites projected to muscle layers and the enteric ganglia of the recipient mice. These findings show that transplanted enteric neural progenitor cells can generate functional enteric neurons in the postnatal bowel and advances the notion that cell therapy is a promising strategy for enteric neuropathies.

Disturbances of colonic motility in mouse models of Hirschsprung's disease

Mutations in genes encoding members of the GDNF and endothelin-3 (Et-3) signaling pathways can cause Hirschsprungs disease, a congenital condition associated with an absence of enteric neurons in the distal gut. GDNF signals through Ret, a receptor tyrosine kinase, and Et-3 signals through endothelin receptor B (Ednrb). The effects of Gdnf, Ret, and ET-3 haploinsufficiency and a null mutation in ET-3 on spontaneous motility patterns in adult and developing mice were investigated. Video recordings were used to construct spatiotemporal maps of spontaneous contractile patterns in colon from postnatal and adult mice in vitro. In Ret(+/-) and ET-3(+/-) mice, which have normal numbers of enteric neurons, colonic migrating motor complexes (CMMCs) displayed similar properties under control conditions and following inhibition of nitric oxide synthase (NOS) activity to wild-type mice. In the colon of Gdnf(+/-) mice and in the ganglionic region of ET-3(-/-) mice, there was a 50-60% reduction in myenteric neuron number. In Gdnf(+/-) mice, CMMCs were present, but abnormal, and the proportion of myenteric neurons containing NOS was not different from that of wild-type mice. In the ganglionic region of postnatal ET-3(-/-) mice, CMMCs were absent, and the proportion of myenteric neurons containing NOS was over 100% higher than in wild-type mice. Thus impairments in spontaneous motility patterns in the colon of Gdnf(+/-) mice and in the ganglionic region of ET-3(-/-) mice are correlated with a reduction in myenteric neuron density.

Small-Molecule Induction of Neural Crest-like Cells Derived from Human Neural Progenitors†‡§

Neural crest (NC) cells are stem cells that are specified within the embryonic neuroectodermal epithelium and migrate to stereotyped peripheral sites for differentiation into many cell types. Several neurocristopathies involve a deficit of NC‐derived cells, raising the possibility of stem cell therapy. In Hirschsprungs disease the distal bowel lacks an enteric nervous system caused by a failure of colonization by NC‐derived cells. We have developed a robust method of producing migrating NC‐like cells from human embryonic stem cell–derived neural progenitors using a coculture system of mouse embryonic fibroblasts. Significantly, subsequent exposure to Y27632, a small‐molecule inhibitor of the Rho effectors ROCKI/II, dramatically increased the efficiency of differentiation into NC‐like cells, identified by marker expression in vitro. NC‐like cells derived by this method were able to migrate along NC pathways in avian embryos in ovo and within explants of murine bowel, and to differentiate into cells with neuronal and glial markers. This is the first study to report the use of a small molecule to induce cells with NC characteristics from embryonic stem cells that can migrate and generate neurons and support cells in complex tissue. Furthermore, this study demonstrates that small‐molecule regulators of ROCKI/II signaling may be valuable tools for stem cell research aimed at treatment of neurocristopathies. STEM CELLS 2009;27:2896–2905

Colonizing while migrating: how do individual enteric neural crest cells behave?

BackgroundDirected cell migration is essential for normal development. In most of the migratory cell populations that have been analyzed in detail to date, all of the cells migrate as a collective from one location to another. However, there are also migratory cell populations that must populate the areas through which they migrate, and thus some cells get left behind while others advance. Very little is known about how individual cells behave to achieve concomitant directional migration and population of the migratory route. We examined the behavior of enteric neural crest-derived cells (ENCCs), which must both advance caudally to reach the anal end and populate each gut region.ResultsThe behavior of individual ENCCs was examined using live imaging and mice in which ENCCs express a photoconvertible protein. We show that individual ENCCs exhibit very variable directionalities and speed; as the migratory wavefront of ENCCs advances caudally, each gut region is populated primarily by some ENCCs migrating non-directionally. After populating each region, ENCCs remain migratory for at least 24 hours. Endothelin receptor type B (EDNRB) signaling is known to be essential for the normal advance of the ENCC population. We now show that perturbation of EDNRB principally affects individual ENCC speed rather than directionality. The trajectories of solitary ENCCs, which occur transiently at the wavefront, were consistent with an unbiased random walk and so cell-cell contact is essential for directional migration. ENCCs migrate in close association with neurites. We showed that although ENCCs often use neurites as substrates, ENCCs lead the way, neurites are not required for chain formation and neurite growth is more directional than the migration of ENCCs as a whole.ConclusionsEach gut region is initially populated by sub-populations of ENCCs migrating non-directionally, rather than stopping. This might provide a mechanism for ensuring a uniform density of ENCCs along the growing gut.

The first intestinal motility patterns in fetal mice are not mediated by neurons or interstitial cells of Cajal

In mature animals, neurons and interstitial cells of Cajal (ICC) are essential for organized intestinal motility. We investigated motility patterns, and the roles of neurons and myenteric ICC (ICC‐MP), in the duodenum and colon of developing mice in vitro. Spatiotemporal mapping revealed regular contractions that propagated in both directions from embryonic day (E)13.5 in the duodenum and E14.5 in the colon. The propagating contractions, which we termed ripples, were unaffected by tetrodotoxin and were present in the intestine of embryonic Ret null mutant mice, which lack enteric neurons. Neurally mediated motility patterns were first observed in the duodenum at E18.5. To examine the possible role of ICC‐MP, three approaches were used. First, intracellular recordings from the circular muscle of the duodenum did not detect slow wave activity at E16.5, but regular slow waves were observed in some preparations of E18.5 duodenum. Second, spatiotemporal mapping revealed ripples in the duodenum of E13.5 and E16.5 W/Wv embryos, which lack KIT+ ICC‐MP and slow waves. Third, KIT‐immunoreactive cells with the morphology of ICC‐MP were first observed at E18.5. Hence, ripples do not appear to be mediated by ICC‐MP and must be myogenic. Ripples in the duodenum and colon were abolished by cobalt chloride (1 mm). The L‐type Ca2+ channel antagonist nicardipine (2.5 μm) abolished ripples in the duodenum and reduced their frequency and size in the colon. Our findings demonstrate that prominent propagating contractions (ripples) are present in the duodenum and colon of fetal mice. Ripples are not mediated by neurons or ICC‐MP, but entry of extracellular Ca2+ through L‐type Ca2+ channels is essential. Thus, during development of the intestine, the first motor patterns to develop are myogenic.

Birthdating of myenteric neuron subtypes in the small intestine of the mouse.

There are many different types of enteric neurons. Previous studies have identified the time at which some enteric neuron subtypes are born (exit the cell cycle) in the mouse, but the birthdates of some major enteric neuron subtypes are still incompletely characterized or unknown. We combined 5‐ethynynl‐2′‐deoxyuridine (EdU) labeling with antibody markers that identify myenteric neuron subtypes to determine when neuron subtypes are born in the mouse small intestine. We found that different neurochemical classes of enteric neuron differed in their birthdates; serotonin neurons were born first with peak cell cycle exit at E11.5, followed by neurofilament‐M neurons, calcitonin gene‐related peptide neurons (peak cell cycle exit for both at embryonic day [E]12.5–E13.5), tyrosine hydroxylase neurons (E15.5), nitric oxide synthase 1 (NOS1) neurons (E15.5), and calretinin neurons (postnatal day [P]0). The vast majority of myenteric neurons had exited the cell cycle by P10. We did not observe any EdU+/NOS1+ myenteric neurons in the small intestine of adult mice following EdU injection at E10.5 or E11.5, which was unexpected, as previous studies have shown that NOS1 neurons are present in E11.5 mice. Studies using the proliferation marker Ki67 revealed that very few NOS1 neurons in the E11.5 and E12.5 gut were proliferating. However, Cre‐lox‐based genetic fate‐mapping revealed a small subpopulation of myenteric neurons that appears to express NOS1 only transiently. Together, our results confirm a relationship between enteric neuron subtype and birthdate, and suggest that some enteric neurons exhibit neurochemical phenotypes during development that are different from their mature phenotype. J. Comp. Neurol. 522:514–527, 2014.

How many types of cholinergic sympathetic neuron are there in the rat stellate ganglion

Sympathetic cholinergic postganglionic neurons are present in many sympathetic ganglia. Three classes of sympathetic cholinergic neuron have been reported in mammals; sudomotor neurons, vasodilator neurons and neurons innervating the periosteum. We have examined thoracic sympathetic ganglia in rats to determine if any other classes of cholinergic neurons exist. We could identify cholinergic sudomotor neurons and neurons innervating the rib periosteum, but confirmed that cholinergic sympathetic vasodilator neurons are absent in this species. Sudomotor neurons contained vasoactive intestinal peptide (VIP) and calcitonin gene-related peptide (CGRP) and always lacked calbindin. Cholinergic neurons innervating the periosteum contained VIP and sometimes calbindin, but always lacked CGRP. Cholinergic neurons innervating the periosteum were usually surrounded by terminals immunoreactive for CGRP. We conclude that if any undiscovered populations of cholinergic neurons exist in the rat thoracic sympathetic chain, then they are indistinguishable in size, neurochemistry and inputs from sudomotor or cholinergic neurons innervating the periosteum. It may be that the latter two populations account for all cholinergic neurons in the rat thoracic sympathetic chain ganglia.

Effect of Gdnf haploinsufficiency on rate of migration and number of enteric neural crest-derived cells.

The enteric nervous system arises predominantly from vagal level neural crest cells that migrate into the foregut and then colonize the entire length of the gastrointestinal tract. Previous studies have demonstrated that glial cell line‐derived neurotrophic factor (GDNF) promotes the migration of enteric neural crest‐derived cells (ENCs) in vitro, but a role for GDNF in the migration of ENCs in vivo has yet to be demonstrated. In this study, the effects of Gdnf haploinsufficiency on ENC rate of migration and number during mid embryonic development were examined. Although the entire gut of embryonic Gdnf+/− mice was colonized, a significant delay in the migration of ENCs along the embryonic hindgut was found. However, significant effects of Gdnf haploinsufficiency on ENC number were detected before the stage at which migration defects were first evident. As previous studies have shown a relationship between ENC number and migration, the effects of Gdnf haploinsufficiency on migration may be due to an indirect effect on cell number and/or a direct effect of GDNF on ENC migration. Gdnf haploinsufficiency did not cause any detectable change in the rate of neuronal differentiation of ENCs. Developmental Dynamics 236:134–141, 2007.

After axotomy, substance P and vasoactive intestinal peptide expression occurs in pilomotor neurons in the rat superior cervical ganglion

Autonomic sympathetic postganglionic neurons normally express distinct combinations of neuropeptides which are often highly correlated with the projection of the neurons. When sympathetic postganglionic neurons are axotomized, they can express quite different neuropeptides, notably substance P, vasoactive intestinal peptide or galanin. In this study, we have examined rat sympathetic postganglionic neurons in the superior cervical ganglion that project to the skin, the vasculature of the skeletal muscle or to the submandibular salivary gland, and assessed whether the neuropeptides that they express after axotomy depend on which target tissue they previously innervated. In all three populations, around half of the postganglionic neurons expressed galanin after axotomy. In contrast, only skin-projecting neurons showed a significant increase in the number of neurons that expressed substance P (22%) and vasoactive intestinal peptide (17%) following axotomy. Within the skin-projecting neurons, as judged on the basis of cell body size, substance P and vasoactive intestinal peptide were expressed predominantly in pilomotor neurons, but only rarely were the two neuropeptides present in the same nerve cell body. In conclusion, we have demonstrated that three different neuropeptides, which can be induced by axotomy in postganglionic neurons, follow quite different patterns of expression when they are viewed in relation to the function of the postganglionic neurons in the superior cervical ganglion.