Spatiotemporal mapping of vascularization and innervation in the fetal murine intestine

Background : In mice, the intestinal tube develops from the splanchopleure before embryonic day 9.5. Subsequent patterning of nerves and blood vessels is critical for normal digestive function. A hierarchical branching vascular network allows for efficient nutrient absorption, while the complex enteric nervous system regulates intestinal motility as well as secretion, absorption, and blood flow. Despite the well‐recognized significance of these systems, the precise mechanisms by which they develop have not been clearly established in mammals. Results : Using a novel whole‐mount immunohistochemical protocol, we visualize the pattern of intestinal neurovascular development in mice between embryonic day 10.5 and birth. In particular, we focus on the development and remodeling of the enteric vascular plexus, the migration and organization of enteric neural crest‐derived cells, and the integration of peripheral sympathetic nerves with the enteric nervous system. These correlative data lead us to hypothesize a functional interaction between migrating neural crest‐derived cells and endothelial cells of the primary capillary plexus, as well as a subsequent interaction between developing peripheral autonomic nerves and differentiated neural crest‐derived cells. Conclusions: These studies provide useful anatomical data for continuing investigations on the functional mechanisms underlying intestinal organogenesis. Developmental Dynamics 244:56–68, 2015. Published 2014. This article is a U.S. Government work and is in the public domain in the USA     

Gdnf is mitogenic,neurotrophic, and chemoattractive to enteric neural crest cells in the embryonic colon

Glial‐derived neurotrophic factor (Gdnf) is required for morphogenesis of the enteric nervous system (ENS) and it has been shown to regulate proliferation, differentiation, and survival of cultured enteric neural crest–derived cells (ENCCs). The goal of this study was to investigate its in vivo role in the colon, the site most commonly affected by intestinal neuropathies such as Hirschsprung's disease. Gdnf activity was modulated in ovo in the distal gut of avian embryos using targeted retrovirus‐mediated gene overexpression and retroviral vector‐based gene silencing. We find that Gdnf has a pleiotropic effect on colonic ENCCs, promoting proliferation, inducing neuronal differentiation, and acting as a chemoattractant. Down‐regulating Gdnf similarly induces premature neuronal differentiation, but also inhibits ENCC proliferation, leading to distal colorectal aganglionosis with severe proximal hypoganglionosis. These results indicate an important role for Gdnf signaling in colonic ENS formation and emphasize the critical balance between proliferation and differentiation in the developing ENS. Developmental Dynamics 240:1402–1411, 2011. © 2011 Wiley‐Liss, Inc.     

Glial cell line-derived neurotrophic factor is crucial for long-term maintenance of the nigrostriatal system

Glial cell line-derived neurotrophic factor (GDNF) is a potent factor for the ventral mesencephalic dopamine neurons. However, studies on the Gdnf gene deleted (Gdnf(-/-)) mouse have been limited to fetal tissue since these mice die prematurely. To evaluate long-term effects of Gdnf gene deletion, this study involves co-grafts of ventral mesencephalon (VM) and lateral ganglionic eminence (LGE) derived from different Gdnf genotypes. The VM/LGE co-grafts were evaluated at 3, 6, and 12 months for tyrosine hydroxylase (TH) -positive cell survival and nerve fiber formation in the LGE co-transplant, visualized by dopamine- and cyclic AMP-regulated phosphoprotein relative molecular mass 32,000 (DARPP-32) -immunoreactivity. Cell counts revealed no difference in TH-positive neurons between Gdnf genotypes at 3 months postgrafting. At 6 months, a significant reduction in cell number was observed in the Gdnf(-/-) grafts. In fact, in the majority of the Gdnf(-/-) VM/LGE transplant had degenerated. At 12 months, a reduction in cell number was seen in both Gdnf(-/-) and Gdnf(+/-) compared to wild type transplants. In the Gdnf(-/-) grafts, TH-negative inclusion-like structures were present in the cytoplasm of the TH-positive neurons at 3 months. These structures were also found in the Gdnf(+/-) transplants at 12 months, but not in Gdnf(+/+) controls at any time point. In Gdnf(+/+) grafts, TH-positive nerve fiber innervation of the striatal co-grafts was dense and patchy and overlapped with clusters of DARPP-32-positive neurons. This overlap did mismatch in the Gdnf(+/-) grafts, while the TH-positive innervation was sparse in the Gdnf(-/-) transplants and the DARPP-32-positive neurons were widespread distributed. In conclusion, GDNF is essential for long-term maintenance of both the VM TH-positive neurons and for the striatal tissue, and appears crucial for generation of a proper organization of the striatum.     

Immunophenotypic characterization of enteric neural crest cells in the developing avian colorectum

Background: The enteric nervous system (ENS) develops from neural crest‐derived cells that migrate along the intestine to form two plexuses of neurons and glia. While the major features of ENS development are conserved across species, minor differences exist, especially in the colorectum. Given the embryologic and disease‐related importance of the distal ENS, the aim of this study was to characterize the migration and differentiation of enteric neural crest‐derived cells (ENCCs) in the colorectum of avian embryos. Results: Using normal chick embryos and vagal neural tube transplants from green fluorescent protein (GFP) ‐transgenic chick embryos, we find ENCCs entering the colon at embryonic day (E) 6.5, with colonization complete by E8. Undifferentiated ENCCs at the wavefront express HNK‐1, N‐cadherin, Sox10, p75, and L1CAM. By E7, differentiation begins in the proximal colon, with L1CAM and Sox10 becoming restricted to neuronal and glial lineages, respectively. By E8, multiple markers of differentiation are expressed along the entire colorectum. Conclusions: Our results establish the pattern of ENCC migration and differentiation in the chick colorectum, demonstrate the conservation of marker expression across species, highlight a range of markers, including neuronal cell adhesion molecules, which label cells at the wavefront, and provide a framework for future studies in avian ENS development. Developmental Dynamics 241:842–851, 2012. © 2012 Wiley Periodicals, Inc.     

Behavior of enteric neural crest-derived cells varies with respect to the migratory wavefront.

Neural crest-derived cells colonize the entire gastrointestinal tract. The migration of these enteric neural crest-derived cells (ENCCs) occurs by their formation of cellular strands that extend into the intestinal mesenchyme. We have studied the behavior of crest cells that underlies the formation and extension of these strands by time-lapse microscopy. ENCCs expressing fluorescent marker molecules were visualized in situ in the embryonic mouse and chick gut. The major contributor to strand extension is from cells located within a region approximately 300 microm behind (rostral to) the most caudal cells in the migratory wavefront. Cells in the region immediately behind the leading cell of the strand either move intermittently in parallel with the leading cell, or advance caudally toward the wavefront over other ENCCs. Another addition to the strands arises from isolated cells located caudal to the wavefront. These cells showed a range of behavior including attachment and separation from the strands. The extending strands converged to form nodes, and then diverged along independent paths to form new strands, a behavior suggestive of attraction and repulsion. This behavior is probably responsible for the unique reticulated arrangement of ganglia in the enteric nervous system. As cells become positioned farther behind the wavefront, they exhibit more restricted movement and varied trajectories. We conclude that ENCCs exhibit different behaviors, depending on their position with respect to the wavefront. These different behaviors suggest a critical role for cell-cell interaction in the migratory process.     

Phactr4 regulates directional migration of enteric neural crest through PP1, integrin signaling, and cofilin activity

Hirschsprung disease (HSCR) is caused by a reduction of enteric neural crest cells (ENCCs) in the gut and gastrointestinal blockage. Knowledge of the genetics underlying HSCR is incomplete, particularly genes that control cellular behaviors of ENCC migration. Here we report a novel regulator of ENCC migration in mice. Disruption of the Phactr4 gene causes an embryonic gastrointestinal defect due to colon hypoganglionosis, which resembles human HSCR. Time-lapse imaging of ENCCs within the embryonic gut demonstrates a collective cell migration defect. Mutant ENCCs show undirected cellular protrusions and disrupted directional and chain migration. Phactr4 acts cell-autonomously in ENCCs and colocalizes with integrin and cofilin at cell protrusions. Mechanistically, we show that Phactr4 negatively regulates integrin signaling through the RHO/ROCK pathway and coordinates protein phosphatase 1 (PP1) with cofilin activity to regulate cytoskeletal dynamics. Strikingly, lamellipodia formation and in vivo ENCC chain migration defects are rescued by inhibition of ROCK or integrin function. Our results demonstrate a previously unknown pathway in ENCC collective migration in vivo and provide new candidate genes for human genetic studies of HSCR.     

Cell adhesion molecule L1 affects the rate of differentiation of enteric neurons in the developing gut

The enteric nervous system arises predominantly from vagal level neural crest cells that migrate into and along the developing gut. As the neural crest‐derived cells migrate within the gut, a subpopulation begins to differentiate into enteric neurons. Here, we show that the differentiation of neural crest‐derived cells into enteric neurons is delayed in L1‐deficient mice, compared with littermate controls. However, glial cell differentiation is not affected in L1‐deficient mice. These mice also show a delay in the differentiation of a neurotransmitter‐specific subtype of enteric neuron within the gastrointestinal tract. Together, these results suggest a role for the cell adhesion molecule, L1, in the differentiation of neural crest‐derived cells into enteric neurons within the developing enteric nervous system. Developmental Dynamics 238:708–715, 2009. © 2009 Wiley‐Liss, Inc.     

GDNF promotes neuronal differentiation and dopaminergic development of mouse mesencephalic neurospheres

In the present study we report establishment of a neurosphere culture system derived from mouse ventral mesencephalon at embryonic day 12 and investigate effects of glial cell line-derived neurotrophic factor (GDNF) in the differentiation potential of the neurospheres. The generated neurospheres exhibit stem cell characteristics, i.e. self-renewal capacity and multipotency. Addition of exogenous GDNF resulted in neural differentiation indicated by reduced number of nestin positive cells. GDNF treatment resulted in increased numbers of beta-III-tubulin immunoreactive cells whereas glial fibrillary acidic protein immunoreactivity was not effected. Most importantly, cell numbers expressing early dopaminergic markers, Nurr1 and Ptx3, were significantly higher in GDNF-treated spheres. We conclude that GDNF promotes differentiation of mouse mesencephalic stem cells towards neuronal lineage and most notably dopaminergic development.     

Trans-mesenteric neural crest cells are the principal source of the colonic enteric nervous system

Cell migration is fundamental to organogenesis. During development, the enteric neural crest cells (ENCCs) that give rise to the enteric nervous system (ENS) migrate and colonize the entire length of the gut, which undergoes substantial growth and morphological rearrangement. How ENCCs adapt to such changes during migration, however, is not fully understood. Using time-lapse imaging analyses of mouse ENCCs, we show that a population of ENCCs crosses from the midgut to the hindgut via the mesentery during a developmental time period in which these gut regions are transiently juxtaposed, and that such 'trans-mesenteric' ENCCs constitute a large part of the hindgut ENS. This migratory process requires GDNF signaling, and evidence suggests that impaired trans-mesenteric migration of ENCCs may underlie the pathogenesis of Hirschsprung disease (intestinal aganglionosis). The discovery of this trans-mesenteric ENCC population provides a basis for improving our understanding of ENS development and pathogenesis.     

低氧环境下胶质源性神经营养因子体外诱导中脑神经干细胞的分化

背景：有效的神经干细胞体外增殖与多巴胺能神经元的定向诱导分化是神经干细胞移植治疗帕金森病的关键所在。 目的：观察低氧条件下胶质源性神经营养因子体外诱导中脑源性神经干细胞向多巴胺能神经元的分化。 方法：体外分离培养孕12 d胚鼠腹侧中脑组织,制成单细胞悬液,在含碱性成纤维细胞生长因子和B27的无血清培养基中培养并传代,分别置于常氧(体积分数21%O₂)或低氧(体积分数3%O₂)环境下增殖5~7 d后,接种于含体积分数10%胎牛血清的DMEM/F12培养基,或含体积分数10%胎牛血清的DMEM/F12+1 µg/L胶质源性神经营养因子。 结果与结论：低氧环境下分化10~12 d,中脑神经干细胞向多巴胺能神经元分化均高于常氧组,在胶质源性神经营养因子诱导下向多巴胺能神经元分化比例更高,表型更成熟。说明低氧环境下胶质源性神经营养因子可明显促进中脑神经干细胞分化为数量足够、形态及功能成熟的多巴胺能神经元。     

Enteric Neurogenesis During Life Span Under Physiological and Pathophysiological Conditions

The enteric nervous system (ENS) controls gastrointestinal key functions and is mainly characterized by two ganglionated plexus located in the gut wall: the myenteric plexus and the submucous plexus. The ENS harbors a high number and diversity of enteric neurons and glial cells, which generate neuronal circuitry to regulate intestinal physiology. In the past few years, the pivotal role of enteric neurons in the underlying mechanism of several intestinal diseases was revealed. Intestinal diseases are associated with neuronal death that could in turn compromise intestinal functionality. Enteric neurogenesis and regeneration is therefore a crucial aspect within the ENS and could be revealed not only during embryogenesis and early postnatal periods, but also in the adulthood. Enteric glia and/or enteric neural precursor/progenitor cells differentiate into enteric neurons, both under homeostatic and pathologic conditions beyond the perinatal period. The unique role of the intestinal microbiota and serotonin signaling in postnatal and adult neurogenesis has been shown by several studies in health and disease. In this review article, we will mainly focus on different recent studies, which advanced the concept of postnatal and adult ENS neurogenesis. Moreover, we will discuss the key factors and underlying mechanisms, which promote enteric neurogenesis. Finally, we will shortly describe neurogenesis of transplanted enteric neural progenitor cells. Anat Rec, 302:1345–1353, 2019. © 2019 Wiley Periodicals, Inc.     

Balancing neural crest cell intrinsic processes with those of the microenvironment in Tcof1 haploinsufficient mice enables complete enteric nervous system formation

The enteric nervous system (ENS) comprises a complex neuronal network that regulates peristalsis of the gut wall and secretions into the lumen. The ENS is formed from a multipotent progenitor cell population called the neural crest, which is derived from the neuroepithelium. Neural crest cells (NCCs) migrate over incredible distances to colonize the entire length of the gut and during their migration they must survive, proliferate and ultimately differentiate. The absence of an ENS from variable lengths of the colon results in Hirschsprung's disease (HSCR) or colonic aganglionosis. Mutations in about 12 different genes have been identified in HSCR patients but the complex pattern of inheritance and variable penetrance suggests that additional genes or modifiers must be involved in the etiology and pathogenesis of this disease. We discovered that Tcof1 haploinsufficiency in mice models many of the early features of HSCR. Neuroepithelial apoptosis diminished the size of the neural stem cell pool resulting in reduced NCC numbers and their delayed migration along the gut from E10.5 to E14.5. Surprisingly however, we observe continued and complete colonization of the entire colon throughout E14.5-E18.5, a period in which the gut is considered to be non- or less-permissive to NCC. Thus, we reveal for the first time that reduced NCC progenitor numbers and delayed migration do not unequivocally equate with a predisposition for the pathogenesis of HSCR. In fact, these deficiencies can be overcome by balancing NCC intrinsic processes of proliferation and differentiation with extrinsic influences of the gut microenvironment.     

Regulation of neural development by glial cell line-derived neurotrophic factor family ligands

Glial cell line-derived neurotrophic factor (GDNF) and its three relatives constitute a novel family of neurotrophic factors, the GDNF family ligands. These factors signal through a multicomponent receptor complex comprising a glycosylphosphatidylinositol-anchored cell surface molecule (GDNF family receptor (GFR) alpha) and RET tyrosine kinase, triggering the activation of multiple signaling pathways in responsive cells. Recent gene-targeting studies have demonstrated that GDNF family ligands are essential for the development of a diverse set of neuronal populations and we have now started to understand how these ligands uniquely regulate the formation and sculpting of the nervous system. Recent studies have also revealed interactions by multiple extracellular signals during neural development. The deciphering of GDNF family ligand signaling in neural cells promises to provide vital new insights into the development and pathology of the nervous system.     

Gut feelings: Studying enteric nervous system development,function, and disease in the zebrafish model system

The enteric nervous system (ENS) is the largest part of the peripheral nervous system and is entirely neural crest–derived. It provides the intrinsic innervation of the gut, controlling different aspects of gut function, such as motility. In this review, we will discuss key points of Zebrafish ENS development, genes, and signaling pathways regulating ENS development, as well as contributions of the Zebrafish model system to better understand ENS disorders. During their migration, enteric progenitor cells (EPCs) display a gradient of developmental states based on their proliferative and migratory characteristics, and show spatiotemporal heterogeneity based on gene expression patterns. Many genes and signaling pathways that regulate the migration and proliferation of EPCs have been identified, but later stages of ENS development, especially steps of neuronal and glial differentiation, remain poorly understood. In recent years, Zebrafish have become increasingly important to test candidate genes for ENS disorders (e.g., from genome‐wide association studies), to identify environmental influences on ENS development (e.g., through large‐scale drug screens), and to investigate the role the gut microbiota play in ENS development and disease. With its unique advantages as a model organism, Zebrafish will continue to contribute to a better understanding of ENS development, function, and disease. Developmental Dynamics 247:268–278, 2018. © 2017 Wiley Periodicals, Inc.     

Increased glial‐derived neurotrophic factor in the small intestine of rats infected with the tapeworm,Hymenolepis diminuta

The neurotrophin, glial‐derived neurotrophic factor (GDNF), is essential for the development of the enteric nervous system (ENS) in both the embryo and neonate and may be important for maintenance and plasticity of ENS. The tapeworm, Hymenolepis diminuta, altered the number of cells containing GNDF in the host’s jejunum and ileum. Numbers and locations of GDNF‐containing cells were determined by applying monoclonal anti‐GDNF antibody to intestinal segments collected from infected and uninfected age‐matched rats during the initial 34 days post‐infection (dpi). Most cells staining positive for GDNF were present in the lamina propria of the jejunum and ileum from both infected and uninfected rats. The co‐localization of staining by the antibodies, anti‐GDNF and anti‐ED2 (a nuclear specific antibody for resident macrophages) indicated that at least 74% of the cells staining for GDNF were macrophages. Mast cells did not stain with the anti‐GDNF antibody. The increased number of GDNF+ cells in the infected rat intestine suggests that this neurotrophin may play a role in the neural and mucosal responses to lumenal tapeworm infection.     

Effects of intra-striatal GDNF on motor coordination and striatal electrophysiology in aged F344 rats

The purpose of this study was to examine whether improvement in motor function could be demonstrated in old rats, and to see if GDNF affected post-synaptic DA function. Aged (20 month old) versus young rats were tested following GDNF treatment for postural control by using an inclined balance beam and a wire grip strength test. Rats were also examined electrophysiologically for spontaneous striatal cell firing rate alone and in the presence of DA receptor agonists, and histologically for the intensity of striatal TH staining, and number of DA containing nigral cells. Behavior was significantly improved in the aged animals who received central GDNF infusions, although the extent of improvement was less than what has been observed in 16-month-old rats. There was no effect of GDNF treatment in the aged animals on spontaneous firing rate in the striatum, or on the post synaptic response to locally applied D(1) and D(2) receptor family agonists. However, there was an effect of age alone on firing rate, and on the response to locally applied SKF 38393 and quinpirole. By using unbiased cell counting we observed no age-related decline in the number of TH positive cells in the substantia nigra. There was no effect of GDNF on the number of TH positive cells in the substantia nigra in either young or aged rats, although there were morphological improvements in DA neurons of the GDNF treated aged rats. These results replicate earlier studies showing an effect of age on striatal firing rate and dopamine receptor function, and suggest that the GDNF mediated improvement in behavior may be located other than post synaptically within the striatum.     

胶质细胞源性神经营养因子基因修饰骨髓基质干细胞移植脑出血大鼠 神经营养因子的表达

背景：研究证实,细胞移植和神经营养因子相结合治疗脑损伤能促进大鼠神经功能的恢复。 目的：观察移植胶质细胞源性神经营养因子基因修饰的骨髓基质干细胞对大鼠脑出血后神经营养因子表达的影响。 方法：通过脑立体定位仪向SD大鼠脑尾壳核注射胶原酶和肝素建立脑出血动物模型,将48只模型鼠随机分为3组,骨髓基质干细胞组、胶质细胞源性神经营养因子/骨髓基质干细胞组和对照组于建模后第3天在脑出血部位分别移植骨髓基质干细胞、胶质细胞源性神经营养因子/骨髓基质干细胞以及生理盐水。 结果与结论：与对照组和骨髓基质干细胞组相比,胶质细胞源性神经营养因子/骨髓基质干细胞组大鼠神经功能恢复更好;与对照组相比,移植后1,2周其他2组各神经营养因子表达均显著增加(P < 0.05)。提示胶质细胞源性神经营养因子基因修饰的骨髓基质干细胞移植治疗脑出血大鼠比单纯骨髓基质干细胞有更好的神经保护作用。     

Glial cell-derived neurotrophic factor (GDNF) promotes low-grade Hs683 glioma cell migration through JNK, ERK-1/2 and p38 MAPK signaling pathways

Invasion of tumor cells is the primary cause of therapeutic failure in the treatment of malignant gliomas. In an attempt to investigate the properties of the malignant progression of glioma cells, we examined the correlation between cell migration and glial cell-derived neurotrophic factor (GDNF) secretion of two glioma cell lines which differ in their invasive phenotypes. Here, we show that the high-grade C6 cells are more migrative and secrete more GDNF than the low-grade Hs683 cells. GDNF signaling is more highly activated in C6 cells than in Hs683 cells. Treatment of the Hs683 cells with GDNF significantly increased migration comparable to the C6 cells, revealing the autocrine and/or paracrine effect of GDNF on promotion of the glioma cell migration. We then examined the involvement of mitogen-activated protein kinases (MAPKs) including c-Jun N-terminal protein kinase (JNK), extracellular signal-regulated kinases (ERKs) and p38 MAPK in Hs683 cell migration induced by GDNF. A prominent activation of JNK, ERKs and p38 MAPK was observed in the GDNF-treated cells. Functional studies showed that the activation of these MAPKs was critical for Hs683 cell migration induced by GDNF. Our findings revealing molecular mechanisms for the promoting effect of GDNF on glioma cell migration may provide an insight into a better understanding to the malignant progression of human gliomas.     

Role of the extracellular matrix in neural crest cell migration

Development of the neural crest involves a remarkable feat of coordinated cell migration in which cells detach from the neural tube, take varying routes of migration through the embryonic tissues and then differentiate at the end of their journey to participate in the formation of a number of organ systems. In general, neural crest cells appear to migrate without the guidance of long-range physical or chemical cues, but rather they respond to heterogeneity in the extracellular matrix that forms their migration substrate. Molecules such as fibronectin and laminin act as permissive substrate components, encouraging neural crest cell attachment and spreading, whereas chondroitin sulphate proteoglycans are nonpermissive for migration. A balance between permissive and nonpermissive substrate components seems to be necessary to ensure successful migration, as indicated by a number of studies in mouse mutant systems where nonpermissive molecules are over-expressed, leading to inhibition of neural crest migration. The neural crest expresses cell surface receptors that permit interaction with the extracellular matrix and may also modify the matrix by secretion of proteases. Thus the principles that govern the complex migration of neural crest cells are beginning to emerge.