Development of serotonergic neurons in the chick duodenum

ENS Development Research Since 1983: Great Strides but Many Remaining Challenges

The first enteric nervous system (ENS) conference, organized by Marcello Costa and John Furness, was held in Adelaide, Australia in 1983. In this article, we review what was known about the development of the ENS in 1983 and then summarize some of the major advances in the field since 1983.

Genetic fate-mapping of tyrosine hydroxylase-expressing cells in the enteric nervous system

BACKGROUND

During development of the enteric nervous system, a subpopulation of enteric neuron precursors transiently expresses catecholaminergic properties. The progeny of these transiently catecholaminergic (TC) cells have not been fully characterized.

METHODS

We combined in vivo Cre-lox-based genetic fate-mapping with phenotypic analysis to fate-map enteric neuron subtypes arising from tyrosine hydroxylase (TH)-expressing cells.

KEY RESULTS

Less than 3% of the total (Hu(+) ) neurons in the myenteric plexus of the small intestine of adult mice are generated from transiently TH-expressing cells. Around 50% of the neurons generated from transiently TH-expressing cells are calbindin neurons, but their progeny also include calretinin, neurofilament-M, and serotonin neurons. However, only 30% of the serotonin neurons and small subpopulations (<10%) of the calbindin, calretinin, and neurofilament-M neurons are generated from TH-expressing cells; only 0.2% of nitric oxide synthase neurons arise from TH-expressing cells.

CONCLUSIONS & INFERENCES

Transiently, catecholaminergic cells give rise to subpopulations of multiple enteric neuron subtypes, but the majority of each of the neuron subtypes arises from non-TC cells.

Development of the autonomic nervous system: a comparative view

In this review we summarize current understanding of the development of autonomic neurons in vertebrates. The mechanisms controlling the development of sympathetic and enteric neurons have been studied in considerable detail in laboratory mammals, chick and zebrafish, and there are also limited data about the development of sympathetic and enteric neurons in amphibians. Little is known about the development of parasympathetic neurons apart from the ciliary ganglion in chicks. Although there are considerable gaps in our knowledge, some of the mechanisms controlling sympathetic and enteric neuron development appear to be conserved between mammals, avians and zebrafish. For example, some of the transcriptional regulators involved in the development of sympathetic neurons are conserved between mammals, avians and zebrafish, and the requirement for Ret signalling in the development of enteric neurons is conserved between mammals (including humans), avians and zebrafish. However, there are also differences between species in the migratory pathways followed by sympathetic and enteric neuron precursors and in the requirements for some signalling pathways.

Development of enteric neurons from non-recognizable precursor cells

Precursors of the neurons that populate enteric ganglia cannot be recognized morphologically when they first enter the gut; therefore embryonic gut in culture, explanted before neurons appear, develops a myenteric plexus that contains cholinergic and serotonergic neurons. The evidence indicates that the developing gut maintains an immature proliferating pool of neuronal precursors that may tentatively and transiently express a given neuronal phenotype. Catecholaminergic expression is an example of such a transient phenotype. It is possible that sequential changes, occurring as a function of gestational age in the enteric neuronal microenvironment and interacting with this persistent pool of neuronal precursors, are responsible for the generation of enteric neuronal diversity. The sequential appearance of the various types of enteric neuron is consistent with this hypothesis. The persistence of a dividing cell population may also be linked to the generation of the large number of enteric neurons.

Enteric nervous system: development and developmental disturbances--part 2

This review, which is presented in two parts, summarizes and synthesizes current views on the genetic, molecular, and cell biological underpinnings of the early embryonic phases of enteric nervous system (ENS) formation and its defects. Accurate descriptions of the phenotype of ENS dysplasias, and knowledge of genes which, when mutated, give rise to the disorders (see Part 1 in the previous issue of this journal), are not sufficient to give a real understanding of how these abnormalities arise. The often indirect link between genotype and phenotype must be sought in the early embryonic development of the ENS. Therefore, in this, the second part, we provide a description of the development of the ENS, concentrating mainly on the origin of the ENS precursor cells and on the cell migration by which they become distributed throughout the gastrointestinal tract. This section also includes experimental evidence on the controls of ENS formation derived from classic embryological, cell culture, and molecular genetic approaches. In addition, for reasons of completeness, we also briefly describe the origins of the interstitial cells of Cajal, a cell population closely related anatomically and functionally to the ENS. Finally, a brief sketch is presented of current notions on the developmental processes between the genes and the morphogenesis of the ENS, and of the means by which the known genetic abnormalities might result in the ENS phenotype observed in Hirschsprung's disease.

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

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.

Structural study on the appearance of innervation in the stomach of mouse and rat embryos

The stomach of developing embryos was examined by light and electron microscopy on specimens taken at each embryonic day from 11 to 17 (rat) and from 10 to 16 (mouse). The aim of the study was to determine when the precursor cells of enteric neurons and endocrine cells colonize the stomach and when they begin to express morphologic features of mature cells. The findings show that the elements of the enteric nervous system are recognizable and functionally mature prior to the appearance of morphologically detectable gut epithelial endocrine cells. Some aspects of neuronal differentiation in the wall of the stomach are also discussed.

Enteric nervous system and endocrine cells demonstrated in the gut in teratomas

A case of retroperitoneal teratoma, showing considerable morphological development presented as an encapsulated and pedunculated tumour with a seemingly mature intestinal loop. Markedly complex intramural nerve plexuses and numerous epithelial endocrine cells were revealed immunohistochemically in the gut tissue. Ten other mature teratomas containing gastrointestinal tissues were examined for comparison, but neither intramural ganglia nor nervous networks were found in the gut components, despite the presence of amine- and/or peptide-containing endocrine cells in all intestinal mucosa linings. Enteric endocrine cells were found to occur irrespective of the differentiation of intestinal layers or the occurrence of neural elements. These findings suggest that the epithelial endocrine cells of intestinal mucosa do not have the same origin as enteric neurons, but are rather of endodermal origin. This invertebrate well-formed teratoma, containing a highly organized enteric nervous system, suggests that teratoma and fetus in fetus are related entities distinguished by the presence of a vertebral axis.

An electrophysiological study of developmental changes in the innervation of the guinea-pig taenia coli

A sucrose-gap technique was used to study the development of neuromuscular transmission in the taenia coli of fetal, 1- to 2-day-old, 3- to 4-week-old and 3-month-old guinea-pigs. In addition, the effects of exogenous, alpha,beta-methylene adenosine 5'-triphosphate (ATP), noradrenaline, vasoactive intestinal polypeptide (VIP) and carbachol were examined. Taking the response to a single pulse of electrical field stimulation as the index of a developed neuromuscular junction, it was apparent that the non-adrenergic inhibitory system arose before, and matured more quickly than, the cholinergic system. The inhibitory system was present by 8 weeks of gestation in some fetuses, but, in contrast, excitatory cholinergic transmission was not seen until birth. As evidenced by responses to carbachol, alpha,beta-methylene ATP and VIP, cholinergic, purinergic and VIP receptors were present on the smooth muscle at the earliest ages studied. No changes in sensitivity to these agents were noted throughout development, although in adults the level of the maximum responses increased.

Relationship between appearance of GABA, fluorogenic monoamines and cytochrome oxidase activity during prenatal morphogenesis of chick myenteric plexus

The basic histology of the developing embryonic gut wall of the chick was examined on haematein and eosin-stained paraffin sections. In parallel with this, the ontogenic sequence of myenteric plexus formation was followed on whole mounts after NADH diaphorase histochemistry. The presence of nerve elements was verified also by electron microscopy. The appearance of enteric gamma-aminobutyric acid-containing neurons, as an example of an intrinsic inhibitory neuronal system, was studied by using an antiserum against the gamma-aminobutyric acid glutaraldehyde bovine serum albumin conjugate. The development of noradrenergic innervation as an extrinsic inhibitory supply was followed by means of a glyoxylic acid-induced fluorescence method. Cytochrome oxidase activity was detected histochemically. Three consecutive steps of the morphogenesis of the myenteric plexus were revealed; first the appearance of a cellular crest at the mesenteric border on embryonic day 9; second the migration and clustering of nerve cells between embryonic days 10 and 16; then the elongation of neurites on embryonic days 16 and 21. Immunoreactive and also fluorescent fibres were first detected on the 14th day of incubation, while immunopositive cell bodies appeared only after hatching. In the early stages the cytochrome oxidase activity was restricted to the perikarya, while at the end of embryonic development the activity also appeared in the ganglionic neuropile. On the basis of these observations, we concluded that there is a close time relation between the morphogenesis and the biochemical and functional maturation of the myenteric plexus.

Appearance of somatostatin and vasoactive intestinal peptide along the developing chicken gut

The appearance of somatostatin (SOM)-immunoreactive (IR) and vasoactive intestinal peptide (VIP)-IR neurons in different regions of the embryonic chicken gut was studied by immunostaining wholemounts. The patterns of expression of these peptides in myenteric neurons showed a number of similarities. Both peptides first appeared in the region of the proventriculus-gizzard: SOM at embryonic day (E)4, VIP at E5.5. At later times both peptides were found in positions both rostral and caudal to the gizzard. Both peptides appeared independently in cells at a second site, the cecum of the hindgut: SOM was observed at E6.5 and VIP at E7.5. VIP-IR and SOM-IR cells appear throughout the cecum, then in the rectum, and finally in the ileum. Differences in the patterns of expression were also found. SOM- and VIP-IR neurons appeared at different times along the length of the gut. VIP-IR cells populated the entire gut by E11.5, whereas SOM-IR cells were not present throughout the gut until E13.5. SOM-IR cells appeared in the terminal part of the ganglion of Remak at E4.0. At E6 these SOM-IR cells sent fibers into the wall of the hindgut and later into the midgut. No VIP-IR cells were found in the ganglion of Remak. These findings suggest that neural crest-derived cells first express SOM- and VIP-IR in particular regions of the gut, namely, the proventriculus-gizzard and the cecum. Certain conditions must exist at these sites which favor the expression of these neuropeptides by neural crest-derived cells. The observation of SOM- and VIP-IR cells in the cecum at a stage of development before cells are seen in the ileum supports the concept that sacral neural crest cells contribute precursors for enteric neurons of the avian hindgut.

Extension of sympathetic neurites in vitro towards explants of embryonic and neonatal mouse heart and stomach: ontogeny of neuronotrophic factors

In order to establish when target organs first produce neuronotrophic factors, extension of neurites in vitro from sympathetic ganglia (superior cervical and coeliac) of 1-day neonatal mice towards explants of 10-, 11-, 14- and 17-day embryonic and 1-day neonatal atrium and stomach was examined in co-cultures. Longer neurites extended from ganglia towards, than away from, atrial targets at all stages examined, and was most marked towards 17-day embryonic and neonatal explants. Treatment of atrial co-cultures with antiserum to nerve growth factor (NGF) almost totally blocked preferential neurite outgrowth. Directional growth of neurites towards stomach explants in co-cultures was not as pronounced as that towards atrium; extension of neurites was most marked when stomach was provided by 11-, 14- and 17-day embryos. Such outgrowth was only partially blocked by antiserum to NGF, significant preferential extension of neurites towards stomach persisting in the presence of the antiserum. These results indicate that atrium and stomach produce neuronotrophic factors from the earliest ages studied; the evidence indicates that in the case of atrium, NGF predominates but that stomach produces NGF as well as another factor immunologically distinct from NGF. It is of interest that both types of target explanted before they receive sympathetic innervation show evidence of producing NGF in culture.

Development of cholinergic nerve transmission in the chick oesophagus

1. The onset and development of cholinergic mechanisms in the smooth muscle of the chick oesophagus were studied by estimating the changes in mechanical response and biochemical parameters between 9 days of incubation and 7 days after hatching. 2. Transmural and vagal nerve stimulation first evoked contraction in the oesophagus at 10 days and 11 days of incubation, respectively. These contractions were inhibited by atropine (1-2 microM) and potentiated by physostigmine (0.2 microM). On the other hand, hexamethonium (200 microM) had an inhibitory effect on vagal nerve stimulation but not on transmural nerve stimulation. 3. The relative amplitude of contraction induced by both vagal nerve and transmural stimulations compared to high K+ (80 mM)-induced contractions, progressively increased with age in embryos up to 19 days of incubation. 4. The activity of choline acetyltransferase (ChAT), an enzyme synthesizing acetylcholine (ACh), also gradually increased in the oesophagus during the period from 9 days to 19 days of incubation, which was similar to the change in the nerve-mediated contraction. On the other hand, the cholinesterase activity reached a maximum at 13 days of incubation and decreased until 7 days after hatching. 5. The contractile response to ACh and binding sites of [3H]-quinuclidinyl benzilate ([3H]-QNB) were observed in the oesophagus at 9 days of incubation. The maximum response produced by ACh (300 microM) tended to be greater in early stages (9-13 days of incubation) than in later stages. The sensitivity estimated from pD2 values increased up to 15 days of incubation. The maximum response produced by ACh (300 microM) tended to be greater in early stages (9-13 days of incubation) than in later stages. The sensitivity estimated from pD2 values increased up to 15 days of incubation. During the embryonic period, the number of muscarinic receptors estimated from the binding of [3H]-QNB changed very little. 6. These results suggest that in the chick oesophagus, extrinsic and intrinsic cholinergic innervation start to function at 10 days and 11 days of incubation, respectively and continue to develop progressively up to the time of hatching. It seems likely that the functional and biochemical maturation of receptive mechanisms on the smooth muscle precede those of cholinergic innervation.

The distribution of 5-hydroxytryptamine in the gastrointestinal tract of reptiles, birds and a prototherian mammal. An immunohistochemical study

The distribution of 5-hydroxytryptamine in the gut of several species of birds and reptiles, and of a prototherian mammal, the platypus, was studied using a monoclonal antibody. 5-Hydroxytryptamine-like immunoreactivity was found in enterochromaffin cells and, in birds, in thrombocytes. Immunoreactivity was not found in enteric neurons fixed immediately after dissection. A detailed study was made on one avian species, the budgerigar. Following incubation of intestine in physiological solution, immunoreactivity was found in nerve fibres in the gut wall that was more marked after incubation with the monoamine oxidase inhibitor pargyline. These fibres took up exogenous 5-hydroxytryptamine. Similar fibres were found in the intestinal nerves and in perivascular plexuses on mesenteric arteries. Both the uptake of 5-hydroxytryptamine and the appearance of neuronal immunoreactivity after incubation were inhibited by the amine uptake inhibitors desmethylimipramine or fluoxetine. Fibres taking up 5-hydroxytryptamine were damaged by pretreatment with 6-hydroxydopamine. It was concluded that the fibres showing immunoreactivity after incubation were adrenergic fibres that had taken up 5-hydroxytryptamine released in vitro from enterochromaffin cells or thrombocytes. These, and more limited observations made on the other species, suggest that birds, reptiles and prototherian mammals lack enteric neurons that use 5-hydroxytryptamine as a transmitter substance.

Neuromuscular junction development in the cutaneous pectoris muscle of Rana catesbeiana

Synaptic specializations were studied in the developing cutaneous pectoris muscle of Rana catesbeiana tadpoles and froglets to correlate nerve terminal morphology (by light and electron microscopy), accumulation of acetylcholine receptors, and the ability of the muscle to contract following nerve stimulation. This correlated approach was used to determine the developmental timing and possible causal relationship of events in nerve and muscle maturation at the neuromuscular junction. Initially, the cutaneous pectoris nerve trunk was present in the undifferentiated presumptive cutaneous pectoris mesenchyme, prior to muscle maturation. At stage XII when the muscle was first able to contract weakly in response to nerve stimulation, the motor nerve terminal endings were simple bulbous enlargements associated with diffuse subneural aggregations of acetylcholine receptors (indicated by diffuse speckles of rhodamine alpha-bungarotoxin fluorescence). Before stage XII no rhodamine alpha-bungarotoxin fluorescence was present anywhere in the muscle. The first stage in the organization of acetylcholine receptors at the neuromuscular junction was the accumulation of diffuse speckles of fluorescence beneath the terminal enlargements. This was followed by the clustering of receptors into small polygonal areas at each synaptic site, and finally the organization of receptors into parallel linear rows. Presumably this final stage was associated with formation of junctional folds. By stage XV the synapses were multiply innervated and had developed acetylcholinesterase activity. The general nerve terminal morphology and pattern of accumulation of acetylcholine receptors at cutaneous pectoris neuromuscular junctions were similar to those of the adult throughout metamorphic climax except that they still contained more than one motor axon. After metamorphic climax, elimination of multiple innervation occurred.

Origin and morphology of nerve fibers in the aganglionic colon of the lethal spotted (ls/ls) mutant mouse

The lethal spotted mutant mouse (ls/ls) develops congenital megacolon because of the absence of ganglia in the terminal colon. This aganglionosis results from a failure of neural crest cells to colonize this area during fetal life. We have postulated that the microenvironment of the aganglionic segment of bowel is abnormal. Our hypothesis suggests that this abnormal enteric microenvironment fosters the sprouting of neuritic processes. We further propose that neural and glial precursors cease to migrate once they have extended their definitive processes. As a result, the area distal to the site where neurite extension is favored does not become colonized by neural or glial precursors. A prediction of this hypothesis is that the aganglionic tissue should be innervated by axons from neurons located both in the more proximal ganglionated bowel and in ganglia located outside the gut. Neurons and their processes in control and ls/ls terminal gut were located by the histochemical demonstration of acetylcholinesterase (AChE) activity and their structure was classified as intrinsic (enteric) or extrinsic in type by electron microscopy. In ls/ls mice the submucosal plexus was much more severely affected than the myenteric plexus. No submucosal ganglia were found within 30 mm of the anus. In contrast, myenteric ganglia extended to within 4 mm of the anus on the mesenteric side of the gut and to within 15 mm on the antimesenteric side. Rostral to the areas that were absolutely aganglionic, both plexuses were hypoganglionic, especially the submucosal plexus, which was hypoganglionic throughout the entire colon. Both the aganglionic and caudal hypoganglionic zones of the ls/ls bowel were penetrated by large nerve trunks that had the ultrastructural characteristics of extra-enteric peripheral nerve. Unusual ganglia, outside the enteric musculature in the adventitia of the colon, were connected to these trunks. The location of the cell bodies of origin of the nerve fibers in the terminal colon of control mice and in the aganglionic segment of the bowel in ls/ls mice was determined by following the retrograde transport of tracers injected as close as possible to the anus. An extrinsic innervation originating from the inferior mesenteric ganglion and dorsal root ganglia (L6-S1) was found in both types of animal. In control but not ls/ls mice retrograde labeling was also observed in the sacral parasympathetic nucleus of the spinal cord. In addition, neuritic processes were traced to neurons in myenteric ganglia. In control mice, these labeled neurons were present in ganglia within the injection site as well as in bowel rostral and caudal to it.(ABSTRACT TRUNCATED AT 400 WORDS)

Target cell stimulation of dissociated serotonergic neurons in culture

Dissociated mesencephalic raphe cells from fetal rats (14-18 days) were grown in culture in 96 well Linbro plates. The maturation of serotonergic cells was qualitatively studied using immunocytochemistry with a serotonin antibody and quantitatively by measuring the retention of radioactivity following incubation in the presence of a low concentration of [3H]5-hydroxytryptamine (6 X 10(-8) M). The 5-hydroxytryptamine immunoreactive neurons showed specific staining in the perikaryon, nucleus, dendrites, axons and growth cones. These neurons formed varicose fibers and growth cones after 18 h in culture and survived for up to 21 days in culture. Each serotonergic neuron concentrated approximately 1 fmol of serotonin after 20 min of incubation. Maturation of mesencephalic serotonergic neurons was increased in co-cultures of both normal (hippocampus, cerebral cortex, olfactory bulb and striatum) and abnormal (spinal cord) target neurons. The best stimulation was produced by dissociated hippocampal neurons (14-18 days of gestation) on mesencephalic raphe cells (14 days of gestation) after 4 days in culture. This stimulation was seen in culture conditions which favored neuronal but not glial survival. Our results obtained using cultures of dissociated serotonergic cells are consistent with an expansive network pattern developed by this chemical transmitter system in the adult brain.

Analysis of the change in number of serotonergic neurons in the chick spinal cord during embryonic development

The existence of serotonin (5-HT)-containing neurons in the spinal cord of the chick embryo was examined by anti-5-HT immunocytochemistry. The first immunoreactive cells were observed in embryos at 7 days of incubation (E7) and were initially located within the floor plate of the early spinal cord. By E9, immunostained cells occurred throughout the length of the spinal cord and were frequently encountered in most transverse sections of the cord. When examined at later embryonic ages of E12, 17 and at hatching (E21 or 22), the 5-HT cells became progressively more difficult to find with the advancing age of the embryos. To determine if this population of spinal cord 5-HT neurons actually diminished during development, a detailed quantitative analysis was undertaken to estimate the number of 5-HT cells in the cord of chick embryos at different ages. The results of this investigation demonstrated that the size of the 5-HT neuronal population rose rapidly from E7 and plateaued (at approximately 3500 neurons) between E9 and E12. As anticipated, the number of 5-HT cells at E17 decreased at all cord levels. Surprisingly, however, the number of spinal cord 5-HT neurons at hatching increased (depending on the cord level) either back to, or above, the counts estimated for the earlier ages of E9 and E12. Therefore, cells expressing the 5-HT phenotype in the spinal cord of the chick embryo persist throughout the period of embryonic development, rather than appear transiently.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of the monoaminergic innervation of the avian gut: transient and permanent expression of phenotypic markers

Specific cellular accumulation of [3H]5-hydroxytryptamine ([3H]5-HT) occurs during development of the avian gut. This accumulation is transient in extraganglionic mesenchymal cells (TES cells) but is a permanent characteristic of enteric serotonergic neurons (ESN). Species-specific differences were found in the location of TES cells and ESN. In chicks TES cells surrounded myenteric ganglia and ESN were restricted to the myenteric plexus. In quails TES cells surrounded submucosal ganglia and [3H]5-HT-labeled submucosal as well as myenteric neurons. [3H]Norepinephrine accumulated only in noradrenergic terminals and not in TES cells or ESN. The origins of TES cells and ESN were studied in chimeras, in which neuraxis from appropriate or inappropriate axial levels was grafted from quail to chick. Both types of chimeric bowel contained TES cells and ESN. Most TES cells in chimeras were chick in origin and distributed as in chicks (around myenteric ganglia); however, some TES cells and all ESN were quail cells. To test whether crest cells are required for development of TES cells and ESN, aneuronal chick hindgut was explanted and grown alone, or with quail neuraxis, as chorioallantoic membrane (CAM) grafts. TES cells appeared in CAM grafts whether or not crest cells were present; however ESN only appeared in explants when quail neuraxis was included. In addition, an ectopic [3H]5-HT-labeled chromaffin-like cell, also of quail origin, was found in enteric plexuses in these combined explants of crest and gut. Most TES cells, therefore, are neither derived from nor dependent on the presence of crest cells in the gut wall. Since even an inappropriate axial level of crest was found to produce ESN when it was experimentally induced to colonize the bowel the enteric microenvironment probably plays a critical role in serotonergic neural development. The species-specific location of TES cells and ESN is consistent with the hypothesis that TES cells constitute an important component of this microenvironment.

Neurofilament expression in vagal neural crest-derived precursors of enteric neurons

In order to gain insight into the potential role of the enteric microenvironment in the neuronal determination of the neural crest-derived precursor cells of enteric neurons, an attempt was made to ascertain when and where along the migratory route of these cells that they first express neuronal properties. The immunocytochemical detection of the 160-kDa component of the triplet of the chick neurofilament peptides served as a neuronal marker. In addition, neurogenic potential was assessed by growing explants of tissue suspected of containing presumptive neuroblasts in culture or as grafts on the chorioallantoic membrane of chick embryonic hosts. Neurofilament immunoreactivity was first detected in the foregut by Day 4 of development and spread to the hindgut by Day 7. Within the hindgut, development was more advanced within the colorectum than within the more proximal terminal ileum and caecal appendages. This probably reflects the distal-proximal migration of sacral neural crest cells in the postumbilical bowel. The ability of enteric explants to show neuronal development in vitro correlated with whether or not cells containing neurofilament immunoreactivity had reached that segment of gut at the age of explantation. These data suggest that enteric neuronal precursors have already begun to differentiate as neurons by the time they colonize the gut. Prior to the appearance of fibrillar neurofilament immunoreactivity in the foregut, cells that express this marker were found transiently within the mesenchyme of branchial arches 3, 4, and 5. These cells had disappeared from this region by developmental Day 6. The neurogenic potential of branchial arches 3 and 4 was demonstrated by the correlation that was found between the ability of explants of these arches to show neuronal development in vitro and the presence within them of cells that display neurofilament immunoreactivity. No similar neurogenic potential was found in the more rostral branchial arches which lacked the masses of neurofilament-immunoreactive cells. The location of the caudal branchial arches below the migrating vagal neural crest, the transience of the neurofilament immunoreactivity in them, and the coincident transience of their neurogenic potential in vitro, suggested that the masses of neurofilament immunoreactive cells in the caudal branchial arches might be vagal neural crest-derived neuronal precursor cells en route to the pharynx and the rest of the gut.(ABSTRACT TRUNCATED AT 400 WORDS)

Light- and electron-microscopic studies on acetylcholinesterase activity in Auerbach's plexus of the developing rat colon

The distal portions of rat colon from 14-, 16-, 18-, and 21-day fetuses, newborns, and adults were histochemically examined for acetylcholinesterase (AChE) activity by light and electron microscopy. The specificity of AChE activity in Auerbach's plexus was confirmed by specific and/or nonspecific cholinesterase inhibition tests. Enzyme activity was first detectable after 18 days of gestation and became stronger with age. The reaction product was demonstrated by electron microscopy in and between the plasma membranes of the nerve fibers and their terminals. Ganglion cells also showed positive activity in the plasma membrane, nuclear envelope, and rough endoplasmic reticulum. The distribution pattern of the reaction product in fetal and newborn rat colons was basically the same as in adult rat colon. Therefore, the localization of AChE activity is considered to be a good marker for identifying premature ganglion cells in Auerbach's plexus, and the degree of AChE staining is a good indication of the degree of maturation of the plexus.

Evidence for the presence of serotonergic perikarya in the fetal rat pancreas as demonstrated by the high affinity uptake of [3H] 5-HT

Evidence has been obtained for the presence of serotonergic fibers in the adult rat pancreas; however, the location of the serotonergic cell bodies remains unknown. Fetal rat pancreata (18, 20 and 22 days) were demonstrated to possess a high-affinity uptake of serotonin. Radioautography revealed the uptake sites to be similar to those seen in the adult, indicating the presence of serotonergic fibers in early development. In addition, cell bodies, possibly representing primitive neurons, were demonstrated to be heavily labelled. This suggests a possible intra-pancreatic location for the cell bodies of the pancreatic nerves. The preservation of the specific serotonin uptake in 18-day fetal tissue after 4 days in organ culture substantiates this view.

Serotoninergic differentiation of quail neural crest cells in vitro

The in vitro differentiation of quail neural crest cells into serotoninergic neurons is reported. Serotoninergic neurons were identified by two independent methods, formaldehyde-induced histofluorescence and indirect staining with antiserotonin antibodies. Serotonin-positive cells first appeared on the third day in culture, simultaneously, or slightly prior to the first pigmented cells and adrenergic neurons. Comparable numbers of serotoninergic cells were found in crest cell cultures derived from vagal, thoracic/upper lumbar, and lumbosacral levels of the neuraxis. The neural crest origin of the serotonin neurons was further corroborated by the demonstration that cultures of somites, notochords, and neural tubes (three tissues adjacent to the neural crest and thus the most likely contaminants of crest cell cultures) did not contain serotonin-producing cells, and that mast cells were absent in crest cell cultures. The identification of serotoninergic neurons in quail neural crest cell cultures makes an important addition to the number of neural crest derivatives that are capable of differentiating in culture. Furthermore, it suggests that the in vitro culture system will prove a valid approach to the elucidation of the cellular and molecular mechanisms that govern neural crest cell differentiation.

Distribution of vasoactive intestinal polypeptide-, substance P-, enkephalin and neurotensin-like immunoreactive nerves in the chicken gut during development

The ontogeny and distribution of nerve cell bodies and fibres which contain vasoactive intestinal polypeptide-, substance P-, enkephalin- and neurotensin-like immunoreactivity have been studied in the chicken gastrointestinal tract, using immunocytochemistry. All four peptides were found in nerve fibres, with characteristic distribution patterns, which, in the cases of vasoactive intestinal polypeptide, substance P and methionine enkephalin were similar to those described for the mammalian gut. In addition, many of these fibres were shown to arise from intrinsic neurons, since immunoreactive nerve cell bodies for each of the peptides studied were observed. Neurotensin-immunoreactive nerves were confined to the upper part of the tract and neurotensin immunoreactive cell bodies were only observed in embryonic and newly hatched chicken gut. All four peptides were first observed at 11 days of incubation, or Hamburger-Hamilton stage 37, 20 in the upper part of the tract, particularly in the gizzard. Substance P and methionine enkephalin were subsequently seen in more caudal regions, while vasoactive intestinal polypeptide developed from each end of the tract. Adult patterns of immunoreactivity in nerve fibres were achieved during the first week after hatching. A striking observation was that immunoreactive neuronal cell bodies were much more abundant in the gut of young chickens and chicken embryos than in that of adult birds.

Differentiated properties of identified serotonin neurons in dissociated cultures of embryonic rat brain stem

Serotonin neurons in 14-d embryonic rat brain stem were identified by peroxidase-antiperoxidase immunocytochemistry with an affinity-purified antiserotonin antibody. Brain-stem tissue was dissected from 14- or 15-d embryonic rats, dissociated and grown in cell culture for up to 5 wk, and serotonin neurons were identified by immunocytochemistry. Within 24 h of plating, serotonin immunoreactivity was present in 3.3% of neurons. Immunoreactivity in neuronal cell bodies decreased with time, whereas staining of processes increased. The number of serotonin-immunoreactive neurons remained constant at 3-5% over the first 14 d in culture. From 14 to 28 d, the total number of neurons decreased with little change in the number of serotonin neurons, such that, by day 28 in culture, up to 36% of surviving neurons exhibited serotonin immunoreactivity. Similar percentages of cultured brain stem neurons accumulating 3H-serotonin were identified by autoradiography. Uptake was abolished by the serotonin-uptake inhibitor, clomipramine, but was unaffected by excess norepinephrine, or by the norepinephrine-uptake inhibitor, maprotiline. Synthesis of 3H-serotonin was detected after incubation of cultures with 3H-tryptophan, and newly synthesized serotonin was released by potassium depolarization in a calcium-dependent manner. More than 95% of serotonin neurons were destroyed after incubation of cultures with 5,6-dihydroxytryptamine. Brain-stem cultures contained virtually no neurons with the ability to accumulate 3H-norepinephrine or 3H-dopamine. Approximately 40% of brain-stem neurons were labeled with gamma-aminobutyric acid (3H-GABA). However, there was almost no overlap in the surface area of neurons accumulating 3H-serotonin or 3H-GABA.

Development of enkephalinergic neurons in the gut of the chick

The content and distribution of Met-enkephalin immunoreactivity in the developing chick gut was studied by radioimmunoassay and immunocytochemistry. Met-enkephalin was detected by radioimmunoassay in the duodenum of the 5-day chick embryo. The concentration in this region increased 4-fold by 13 days of incubation and declined thereafter to the levels found in the 4-week chicken. The concentration of enkephalin in the midgut increased about 2-fold between 9 and 13 days of incubation and remained constant until hatching. In the 7-day duodenum, metenkephalin immunoreactivity was found in a network of darkly stained nodes (accumulations of ganglion cells) faintly stained internodal nerve bundles; this network of immunoreactivity was localized to the myenteric plexus. By 9 days of incubation, the network was more extensive and the intensity of staining was increased. At 13 days of incubation, varicosities were found in the region of the ganglion cells and in internodal nerve bundles. At this time, immunoreactivity was clearly visualized in the submucosal plexus. In the newly hatched chicken, met-enkephalin was found in nerves within the circular smooth muscle, as well as the myenteric and submucosal plexuses. The early appearance of met-enkephalin in the developing chick enteric nervous system suggests this peptide may act as a primary neurotransmitter in the organization and control of gut motility.