Mitogenic effect of muscle on the neuroepithelium of the developing spinal cord

A previous study revealed that segments of bowel grafted between the neural tube and somites of a younger chick host embryo would induce a unilateral increase in cellularity of the host's neural tube. The current experiments were done to test the hypotheses that muscle tissue in the wall of the gut is responsible for this growth-promoting effect and that the spinal cord enlargement is the result of a mitogenic action on the neuroepithelium. Fragments of skeletal (E8-15) or cardiac muscle (E4-14) were removed from quail embryos and grafted between the neural tube and somites of chick host embryos (E2). Both skeletal and cardiac muscle grafts mimicked the effect of bowel and induced an increase in cell number as well as a unilateral enlargement of the region of the host's neural tube immediately adjacent to the grafts. The growth-promoting effect of muscle-containing grafts was restricted to the neural tube itself and was not seen in proximate dorsal root or sympathetic ganglia. The action of the grafts of muscle was neither species- nor class-specific, since enlargement of the neural tube was observed following implantation of fetal mouse skeletal muscle into quail hosts. Grafts of skeletal muscle or gut increased the number of cells taking up [3H]thymidine in the host's neuroepithelium as early as 9 h following implantation of a graft. The increase in the number of cells entering the S phase of the cell cycle preceded the increase in cell number. These observations demonstrate that muscle-containing tissues can increase the rate of proliferation of neuroepithelial cells when these tissues are experimentally placed together.     

Sacral neural crest cells colonise aganglionic hindgut in vivo but fail to compensate for lack of enteric ganglia

The vagal neural crest is the origin of majority of neurons and glia that constitute the enteric nervous system, the intrinsic innervation of the gut. We have recently confirmed that a second region of the neuraxis, the sacral neural crest, also contributes to the enteric neuronal and glial populations of both the myenteric and the submucosal plexuses in the chick, caudal to the level of the umbilicus. Results from this previous study showed that sacral neural crest-derived precursors colonised the gut in significant numbers only 4 days after vagal-derived cells had completed their migration along the entire length of the gut. This observation suggested that in order to migrate into the hindgut and differentiate into enteric neurons and glia, sacral neural crest cells may require an interaction with vagal-derived cells or with factors or signalling molecules released by them or their progeny. This interdependence may also explain the inability of sacral neural crest cells to compensate for the lack of ganglia in the terminal hindgut of Hirschsprung's disease in humans or aganglionic megacolon in animals. To investigate the possible interrelationship between sacral and vagal-derived neural crest cells within the hindgut, we mapped the contribution of various vagal neural crest regions to the gut and then ablated appropriate sections of chick vagal neural crest to interrupt the migration of enteric nervous system precursor cells and thus create an aganglionic hindgut model in vivo. In these same ablated animals, the sacral level neural axis was removed and replaced with the equivalent tissue from quail embryos, thus enabling us to document, using cell-specific antibodies, the migration and differentiation of sacral crest-derived cells. Results showed that the vagal neural crest contributed precursors to the enteric nervous system in a regionalised manner. When quail-chick grafts of the neural tube adjacent to somites 1-2 were performed, neural crest cells were found in enteric ganglia throughout the preumbilical gut. These cells were most numerous in the esophagus, sparse in the preumbilical intestine, and absent in the postumbilical gut. When similar grafts adjacent to somites 3-5 or 3-6 were carried out, crest cells were found within enteric ganglia along the entire gut, from the proximal esophagus to the distal colon. Vagal neural crest grafts adjacent to somites 6-7 showed that crest cells from this region were distributed along a caudal-rostral gradient, being most numerous in the hindgut, less so in the intestine, and absent in the proximal foregut. In order to generate aneural hindgut in vivo, it was necessary to ablate the vagal neural crest adjacent to somites 3-6, prior to the 13-somite stage of development. When such ablations were performed, the hindgut, and in some cases also the cecal region, lacked enteric ganglionated plexuses. Sacral neural crest grafting in these vagal neural crest ablated chicks showed that sacral cells migrated along normal, previously described hindgut pathways and formed isolated ganglia containing neurons and glia at the levels of the presumptive myenteric and submucosal plexuses. Comparison between vagal neural crest-ablated and nonablated control animals demonstrated that sacral-derived cells migrated into the gut and differentiated into neurons in higher numbers in the ablated animals than in controls. However, the increase in numbers of sacral neural crest-derived neurons within the hindgut did not appear to be sufficiently high to compensate for the lack of vagal-derived enteric plexuses, as ganglia containing sacral neural crest-derived neurons and glia were small and infrequent. Our findings suggest that the neuronal fate of a relatively fixed subpopulation of sacral neural crest cells may be predetermined as these cells neither require the presence of vagal-derived enteric precursors in order to colonise the hindgut, nor are capable of dramatically altering their proliferation or d     

Development of VIP in the peripheral nervous system of avian embryo

The distribution of the VIP containing structures was studied in the gut and in the paravertebral sympathetic ganglia of the quail and chick embryos by immunocytochemistry. In the gut, development of peptidergic nerves followed a craniocaudal gradient. Immunoreactive fibres were first visible in the oesophagus at day 9 in the quail and day 10 in the chick, at 12 days they extended over the whole length of the gut. Cell bodies were localized at day 9 in the foregut and observed in the mid- and hind-gut just before hatching. Transplantations on the chorioallantoic membrane of fragments of various parts of the digestive tract clearly demonstrated that VIP nerve cell bodies belonged to the intrinsic innervation of the gut. Besides the gut, sympathetic paravertebral ganglia contained cells with VIP immunoreactivity detected at day 9 and 10 in quail and chick respectively. In order to find out whether VIP containing neurons differentiated normally in chick embryos in which quail neural crest cells had been implanted at an early stage of development we looked for the appearance of peptidergic neurones in the following situations: when the quail neural primordium had been grafted orthotopically and isochronically into chick host (1) at the adrenomedullary (somites 18-24) and (2) at the vagal (somites 1-7) levels of the neural axis. In all conditions VIP immunoreactivity was observed in quail cells located either in the sympathetic paravertebral ganglia of the trunk at the level of the graft or in the enteric ganglia according to the graft was made at the adrenomedullary and vagal levels respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Colonization of the post-umbilical bowel by cells derived from the sacral neural crest: direct tracing of cell migration using an intercalating probe and a replication-deficient retrovirus

Experiments were done to test the hypothesis that the avian gut is colonized by cells derived from both vagal and sacral regions of the neural crest. A fluorescent dye, diI (1,1-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate), and a replication-deficient retrovirus (LZ10; Galileo et al. 1990) were employed as tracers. Since LZ10 was constructed with lacZ of E. coli as a reporter gene, infected cells were identified by demonstrating beta-galactosidase immunoreactivity. DiI and LZ10 were injected between the neural tube and surface ectoderm (before the migration of crest cells away from the injection sites) at vagal, truncal (diI only), or sacral axial levels. The bowel was examined 4 days later in order to allow crest-derived cells sufficient time to migrate to the gut. Following injections of either tracer into the vagal crest, labelled cells were found in the gizzard and duodenum. When diI or LZ10 was injected into the sacral crest, labelled cells were seen in the post-umbilical bowel and ganglion of Remak. In the hindgut, marked cells were concentrated in the mesenchyme, just internal to the serosa, and were never observed rostral to the umbilicus. No fluorescent cells were ever found in the bowel following truncal injections of diI, although such cells were observed in sympathetic ganglia. Labelled cells were always found in dorsal root ganglia, no matter which tracer or level of the crest was injected. In embryos injected with LZ10, infected cells in the gut and dorsal root ganglia displayed a neural crest marker (NC-1 immunoreactivity). These observations confirm that the gut is colonized by cells from the sacral as well as the vagal region of the neural crest and that the emigrés from the sacral crest are confined to the post-umbilical bowel.     

Differentiation of peptidergic neurones in quail-chick chimaeric embryos

The problem raised in this work was whether peptidergic neurones with vasoactive intestinal peptide (VIP)-and substance P-like immunoreactivity could develop in chimaeric embryos in which quail neural crest cells had been implanted into chick at an early developmental stage. Differentiation of peptide-containing nerve somas was looked for in different situations: i) when the quail neural primordium had been grafted orthotopically and isochronically into the chick host either at the adrenomedullary (level of somites 18-24) or at the vagal (level of somites 1-7) levels of the neural axis; ii) when the quail adrenomedullary neural primordium had been heterotopically implanted at the vagal level of the chick host. In all conditions, VIP- and substance P-like immunoreactivity were observed in a number of quail neurones located either in the peripheral ganglia of the trunk at the level of the graft (in orthotopic grafts of the adrenomedullary neural primordium) or in the enteric ganglia of the chick gut (in the other types of grafts). The developmental stage at which the first neurones become detectable in the host conforms to the genetic characteristics of the effector cells, i.e. they differentiate at the same stage in normal quail neuroblasts and in quail neuroblasts transplanted into the chick host. In contrast, the distribution of the peptidergic neurones in the host depends on the tissue into which the neural crest cells migrate and not on their origin in the neural axis and their fate in normal development.     

The effect of back-transplants of the embryonic gut wall on growth of the neural tube

Experiments in which the developing gut of avian embryos was back-transplanted to permit the bowel to interact with the developing neural tube were undertaken. Segments of intestine from 4-day quail embryos were implanted between the somites and neural tubes of chick embryos of 7 to 24 somites. The spinal cord responded to the presence of the bowel by enlarging unilaterally on the side of the graft. This effect encompassed both gray and white matter and was accompanied by the extension of neuritic projections from the spinal cord into the enteric grafts. The growth-promoting effect of enteric transplants was manifest at all levels of the neural tube where the grafts were made and led to enlargement of the brain as well as the spinal cord; however, truncal neural crest derivatives in the region of the grafts, such as developing sympathetic and spinal ganglia, were unaffected. Neither sham operations nor grafts of ciliary ganglion, lung, pancreas, mesonephros, or rudiment of the eye mimicked the action of the gut. The effect of the bowel was manifest as early as 24 hr following back-transplantation and was found to be due to an increase in the number of cells in the neuroepithelium. The cell responsible for the ability of the gut wall to enhance neuroepithelial proliferation was not identified, but the effect lacked species specificity and could be elicited in the absence of endoderm or neural crest derivatives in the explant. We propose that the musculoconnective tissue of the gut produces a short-range diffusible factor that induces mitogenic activity in the neuroepithelial cells of the neural tube, but not in the crest cells that form sympathetic or sensory ganglia. Since the gut is not normally in apposition to the neural tube, we suggest that the physiological targets of this factor are the specialized crest cells that colonize the bowel and give rise to the enteric nervous system.     

Colonization of the avian hindgut by cells derived from the sacral neural crest

Studies were done to test the hypothesis that the chick hindgut is colonized by emigrés from the sacral region of the neural crest. Crest-derived cells were identified immunocytochemically with the monoclonal antibody, NC-1, and by their ability to give rise to neurons or glia in the bowel. Neurons were recognized by demonstrating acetylcholinesterase activity, neurofilament immunoreactivity, or the immunoreactivity of a neurofilament-associated protein, NAPA-73, with a monoclonal antibody, E/C8. The visualization of glial fibrillary acidic protein immunoreactivity was employed to detect enteric glia. Separate rostral and caudal populations of NC-1-immunoreactive cells were detected in stage 21 embryos (Day E3.5) that extended in continuous streams from the sacral crest to the hindgut. The rostral group, coexpressed neural markers, while the caudal population did not. The rostral, dually labeled cells appeared to become embedded in the mesenchyme of the dorsal bowel by Day E4 and then to enter the mesentery by Day E5 to give rise to the ganglion of Remak. The caudal NC-1-immunoreactive group, which did not express neural markers, appeared to ascend within the colorectum and, in contrast to the rostral cells, fully encircled the gut. NC-1-immunoreactive neurons and glia developed in organotypic tissue cultures and chorioallantoic membrane grafts of both dorsal and ventral halves of the postumbilical bowel explanted at Days E4 and 5, ages known to precede the colonization of the hindgut by cells from the vagal crest. These observations are consistent with the view that NC-1-immunoreactive cells, which do not express neural markers, migrate from the sacral crest to the hindgut. A subset of these cells appears to be capable of giving rise to neurons in vitro, explaining the development of neurons in the explants of the ventral halves of the gut; however, the fate of the sacral crest-derived cells in situ remains to be established.     

Neural and glial phenotypic expression by neural crest cells in culture: effects of control and presumptive aganglionic bowel from ls/ls mice

The enteric nervous system is formed by cells that migrate to the bowel from the neural crest. Previous experiments have established that avian crest cells in vitro will colonize explants of murine bowel and there give rise to neurons. It has been proposed that phenotypic expression by the crest-derived precursors of enteric neurons and glia is critically influenced by the microenvironment these cells encounter within the gut. To test this hypothesis, quail crest cells were cocultured with explants of control or presumptive aganglionic bowel from the ls/ls mutant mouse, and the effects of the enteric tissue on five phenotypic markers of crest cell development were followed. Aganglionosis develops in the terminal region of the colon of the ls/ls mouse because viable crest-derived neural and glial precursors fail to colonize this tissue. Expression of the phenotypic markers in the cocultures was compared with that in cultures of crest alone, crest plus neural tube, and gut grown alone. The markers examined were melanogenesis and immunostaining with antisera to 5-hydroxytryptamine (5-HT) and tyrosine hydroxylase (TH) and the monoclonal antibodies, NC-1 and GlN1. Explants of control, but not presumptive aganglionic ls/ls gut were found to increase the incidence of the expression of 5-HT and NC-1 immunoreactivities; moreover, especially near the gut, the assumption of a neuronal morphology by 5-HT-, NC-1-, and GlN1-immunoreactive cells was also increased. Coincidence of expression of 5-HT with NC-1 and GlN1 immunoreactivities was observed. The effect of the bowel was selective in that the expression of TH immunoreactivity, which is not a marker of mature enteric neurons, was reduced rather than enhanced. The effect of enteric explants on crest cell development was specific in that it was not mimicked by explants of metanephros, which inhibited expression of 5-HT immunoreactivity and the acquisition of a neuritic form by NC-1-immunoreactive cells. It is concluded that the enteric microenvironment affects the phenotypic expression of subsets of crest cells and that this action of the bowel is manifested in vitro. The inability of presumptive aganglionic gut from ls/ls mice to influence neural phenotypic expression may be due to the failure of this tissue to produce putative factor(s) required for the effect or to the inability of the crest-derived precursor cells to migrate into the abnormal enteric tissue.     

Intestinal coelomic transplants: a novel method for studying enteric nervous system development

Normal development of the enteric nervous system (ENS) requires the coordinated activity of multiple proteins to regulate the migration, proliferation, and differentiation of enteric neural crest cells. Much of our current knowledge of the molecular regulation of ENS development has been gained from transgenic mouse models and cultured neural crest cells. We have developed a method for studying the molecular basis of ENS formation complementing these techniques. Aneural quail or mouse hindgut, isolated prior to the arrival of neural crest cells, was transplanted into the coelomic cavity of a host chick embryo. Neural crest cells from the chick host migrated to and colonized the grafted hindgut. Thorough characterization of the resulting intestinal chimeras was performed by using immunohistochemistry and vital dye labeling to determine the origin of the host-derived cells, their pattern of migration, and their capacity to differentiate. The formation of the ENS in the intestinal chimeras was found to recapitulate many aspects of normal ENS development. The host-derived cells arose from the vagal neural crest and populated the graft in a rostral-to-caudal wave of migration, with the submucosal plexus being colonized first. These crest-derived cells differentiated into neurons and glial cells, forming ganglionated plexuses grossly indistinguishable from normal ENS. The resulting plexuses were specific to the grafted hindgut, with quail grafts developing two ganglionated plexuses, but mouse grafts developing only a single myenteric plexus. We discuss the advantages of intestinal coelomic transplants for studying ENS development. This work was supported by NIH K08HD46655 (to A.M.G.).     

Netrins and DCC in the guidance of migrating neural crest-derived cells in the developing bowel and pancreas

Vagal neural crest-derived precursors of the enteric nervous system colonize the bowel by descending within the enteric mesenchyme. Perpendicular secondary migration, toward the mucosa and into the pancreas, result, respectively, in the formation of submucosal and pancreatic ganglia. We tested the hypothesis that netrins guide these secondary migrations. Studies using RT-PCR, in situ hybridization, and immunocytochemistry indicated that netrins (netrins-1 and -3 mice and netrin-2 in chicks) and netrin receptors [deleted in colorectal cancer (DCC), neogenin, and the adenosine A2b receptor] are expressed by the fetal mucosal epithelium and pancreas. Crest-derived cells expressed DCC, which was developmentally regulated. Crest-derived cells migrated out of explants of gut toward cocultured cells expressing netrin-1 or toward cocultured explants of pancreas. Crest-derived cells also migrated inwardly toward the mucosa of cultured rings of bowel. These migrations were specifically blocked by antibodies to DCC and by inhibition of protein kinase A, which interferes with DCC signaling. Submucosal and pancreatic ganglia were absent at E12.5, E15, and P0 in transgenic mice lacking DCC. Netrins also promoted the survival/development of enteric crest-derived cells. The formation of submucosal and pancreatic ganglia thus involves the attraction of DCC-expressing crest-derived cells by netrins.     

Developmental potentialities in the nonneuronal population of quail sensory ganglia

Sensory ganglia taken from quail embryos at E4 to E7 were back-transplanted into the vagal neural crest migration pathway (i.e., at the level of somites 1 to 6) of 8- to 10-somite stage chick embryos. Three types of sensory ganglia were used: (i) proximal ganglia of cranial sensory nerves IX and X forming the jugular-superior ganglionic complex, whose neurons and nonneuronal cells both arise from the neural crest; (ii) distal ganglia of the same nerves, i.e., the petrosal and nodose ganglia in which the neurons originate from epibranchial placodes and the nonneuronal cells from the neural crest; (iii) dorsal root ganglia taken in the truncal region between the fore- and hindlimb levels. The question raised was whether cells from the graft would be able to yield the neural crest derivatives normally arising from the hindbrain and vagal crest, such as carotid body type I and II cells, enteric ganglia, Schwann cells located along the local nerves, and the nonneuronal contingent of cells in the host nodose ganglion. All the grafted cephalic ganglia provided the host with the complete array of these cell types. In contrast, grafted dorsal root ganglion cells gave rise only to carotid body type I and II cells, to the nonneuronal cells of the nodose ganglion, and to Schwann cells; the ganglion-derived cells did not invade the gut and therefore failed to contribute to the host's enteric neuronal system. Coculture on the chorioallantoic membrane of aneural chick gut directly associated with quail sensory ganglia essentially reinforced these results. These data demonstrate that the capacity of peripheral ganglia to provide enteric plexuses varies according to the level of the neuraxis from which they originate.     

GDNF is a chemoattractant for enteric neural cells

In situ hybridization revealed that GDNF mRNA in the mid- and hindgut mesenchyme of embryonic mice was minimal at E10.5 but was rapidly elevated at all gut regions after E11, but with a slight delay (0.5 days) in the hindgut. GDNF mRNA expression was minimal in the mesentery and in the pharyngeal and pelvic mesenchyme adjacent to the gut. To examine the effect of GDNF on enteric neural crest-derived cells, segments of E11.5 mouse hindgut containing crest-derived cells only at the rostral ends were attached to filter paper supports and grown in catenary organ culture. With GDNF (100 ng/ml) in the culture medium, threefold fewer neurons developed in the gut explants and fivefold more neurons were present on the filter paper outside the gut explants, compared to controls. Thus, in controls, crest-derived cells colonized the entire explant and differentiated into neurons, whereas in the presence of exogenous GDNF, most crest-derived cells migrated out of the gut explant. This is consistent with GDNF acting as a chemoattractant. To test this idea, explants of esophagus, midgut, superior cervical ganglia, paravertebral sympathetic chain ganglia, or dorsal root ganglia from E11.5-E12.5 mice were grown on collagen gels with a GDNF-impregnated agarose bead on one side and a control bead on the opposite side. Migrating neural cells and neurites from the esophagus and midgut accumulated around the GDNF-impregnated beads, but neural cells in other tissues showed little or no chemotactic response to GDNF, although all showed GDNF-receptor (Ret and GFRalpha1) immunoreactivity. We conclude that GDNF may promote the migration of crest cells throughout the gastrointestinal tract, prevent them from straying out of the gut (into the mesentery and pharyngeal and pelvic tissues), and promote directed axon outgrowth.     

Experimental analysis of the migration and differentiation of neuroblasts of the autonomic nervous system and of neurectodermal mesenchymal derivatives, using a biological cell marking technique

By isotopic and isochronic transplantations of fragments of quail neural tube into chick, it has been previously shown that enteric ganglion cells arise from the “vagal” (somites 1–7) and the “lumbo-sacral” (behind somite 28) levels of the neural crest, while the trunk region (somites 8–28) gives rise to orthosympathetic ganglion chain and adrenomedullary cells. The latter originate precisely from the neural crest corresponding to somites 18–24 (i.e., “adrenomedullary” level of the crest). Heterotopic transplantations of fragments of quail neural tube into chick have been carried out in the present work. When the “adrenomedullary” level of the quail neural tube is grafted into the “vagal” region of a chick, the crest cells colonize the gut and differentiate into enteric ganglia of Auerbach's and Meissner's plexi. If quail cephalic neural crest is transplanted in the “adrenomedullary” level of a chick, quail cells migrate into the suprarenal glands and differentiate into adrenomedullary cells. Mesectodermal cells migrate laterally, and differentiate into cartilage, dermis and connective tissues. Thus it appears that preferential pathways located at precise levels of the embryo lead crest cells to their definitive sites. On the other hand the differentiation of the autonomic neuroblasts is controlled by the environment in which crest cells are localized at the end of their migration. On the contrary, mesenchymal derivatives of the cephalic neural crest appear to be early determined since they differentiate according to their presumptive fate when transplanted into the trunk.     

A positive correlation between permissiveness of mesoderm to neural crest migration and early DRG growth.

The microenvironment created by grafting rostral somitic halves in place of normal somites leads to the formation of nonsegmented peripheral ganglia (Kalcheim and Teillet, 1989; Goldstein and Kalcheim, 1991) and is mitogenic for neural crest (NC) cells that become dorsal root ganglia (DRG) (Goldstein et al., 1990). We have now extended these studies by using three surgical manipulations to determine how additional mesodermal tissues affected DRG growth in chick embryos. The following experimental manipulations were performed: (1) unilateral deletion of epithelial somites, similar deletions followed by replacing the somites with (2) a three-dimensional collagen matrix, or (3) fragments of quail lateral plate mesoderm. When somites were absent or replaced by collagen matrix, ganglia were unsegmented, and their volumes were decreased by 21% and 12%, respectively, compared to contralateral intact DRG. In contrast, when lateral plate mesoderm was transplanted in place of somitic mesoderm, NC cells migrated into the grafted mesoderm and formed unsegmented DRG whose volumes were increased by 62.6% compared to the contralateral ganglia. These results suggest that although DRG precursors do not require sclerotome to begin migration and condensation processes, DRG size is modulated by the properties of the mesoderm. Permissiveness to migration is positively correlated with an increase in DRG volume. This volume increase observed in grafts of lateral plate mesoderm is likely to result from enhanced proliferation of neural crest progenitors, previously demonstrated for DRG cells in rostral somitic grafts.     

Transiently catecholaminergic (TC) cells in the bowel of the fetal rat: precursors of noncatecholaminergic enteric neurons

Experiments were done to study the fate of transient catecholaminergic (TC) cells that develop in the rodent gut during ontogeny. When they are first detected, at Day E11 in rats, TC cells are distributed along the vagal pathway, in advance of the descending fibers of the vagus nerves, and in the foregut. The early TC cells coexpress the immunoreactivities of several neural markers, including 150-kDa neurofilament protein, peripherin, microtubule associated protein (MAP) 5, and growth-associated protein (GAP)-43, with those of the catecholamine biosynthetic enzymes tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH). All cells in the fetal rat bowel at Day E11 that express neural markers also express TH immunoreactivity. The primitive TC cells also express the immunoreactivities of neural cell adhesion molecule (N-CAM), neuropeptide Y (NPY), and nerve growth factor (NGF) receptor (and NGF receptor mRNA). By Day E12 TC cells are found along the vagal pathway and throughout the entire preumbilical bowel. At this age TC cells acquire additional characteristics, including MAP 2 and synaptophysin immunoreactivities and acetylcholinesterase activity, which indicate that they continue to mature as neurons. In addition, TC cells of the rat are immunostained at Day E12 by the NC-1 monoclonal antibody, which in rats labels multiple cell types including migrating cells of neural crest origin. Despite their neural properties, at least some TC cells divide and therefore are neural precursors and not terminally differentiated neurons. At Day E10 TH mRNA-containing cells were not detected by in situ hybridization; however, by Day E11 TH mRNA was detected in sympathetic ganglia and in scattered cells in the mesenchyme of the foregut and vagal pathway. At this age, the number of enteric and vagal cells containing TH mRNA is about 30% less than the number of cells containing TH immunoreactivity in adjacent sections. The ratio of TH mRNA-containing cells to TH-immunoreactive vagal and enteric cells is even less at Day E12, especially in more caudal regions of the preumbilical bowel. A similar decline in the ratio of TH mRNA-containing to TH-immunoreactive cells was not observed in sympathetic ganglia. After Day E12 TH mRNA cannot be detected in enteric or vagal cells by in situ hybridization; nevertheless, TH immunoreactivity continues to be present through Day E14. DBH, NPY, and NGF receptor immunoreactivities are expressed by TH-immunoreactive transitional cells in the fetal rat gut after TH mRNA is no longer detectable.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mouse-chick neural chimeras

Embryonic chimera production was used to study the developmental processes of the mouse nervous system. The difficulty of performing in situ transplantation experiments of neural primordium of mouse embryo was overcome by isotopic and isochronic grafting of mouse neural tube fragments into chick embryo. Mouse neural tube cells differentiated perfectly in ovo and neural crest cells associated with the grafted neural tube were able to migrate and reach the normal arrest sites of host neural crests. Cranial neural crest cells penetrated into chick facial areas and entered into the development of dental bud structures, participating in vibrissa formation. Depending on graft level, in ovo implanted mouse neural crest cells formed different components of the peripheral nervous system. At trunk level, they located in spinal ganglia and orthosympathetic chains and gave rise to Schwann cells lining the nerves. When implanted into the lumbosacral region, they penetrated into the enteric nervous system. At the precise 18-24 somite level, they colonized host adrenal gland. Mouse neural tube was involved in the mechanisms required to maintain myogenesis in host somites. Furthermore in ovo grafts of mouse cells from genetically modified embryos, in which many mutations induce early death, are particularly useful to investigate cellular events involved in the development of the nervous system and to identify molecular events of embryogenesis.     

Notochordal and foregut abnormalities correlate with elevated neural crest apoptosis in Patch embryos

Although Patch mutants show severe abnormalities in many neural crest-derived structures including the face and the heart, there is a paucity of information characterizing the mechanisms underlying these congenital defects. Via manipulating the genetic background to circumvent early embryonic lethality, our results revealed that Patch phenotypes are most likely due to a significant decrease in migratory neural crest lineage due to diminished neural crest survival and elevated apoptosis. Homozygous mutant neural crest precursors can undergo typical expansion within the neural tube, epithelial-to-mesenchymal transformation, and initiate normal neural crest emigration. Moreover, in vitro explant culture demonstrated that when isolated from the surrounding mesenchyme, Patch mutant neural crest cells (NCCs) can migrate appropriately. Additionally, Patch foregut, notochord and somitic morphogenesis, and Sonic hedgehog expression profiles were all perturbed. Significantly, the timing of lethality and extent of apoptosis correlated with the degree of severity of Patch mutant foregut, notochord, and somite dysfunction. Finally, analysis of Balb/c-enriched surviving Patch mutants revealed that not all the neural crest subpopulations are affected and that Patch mutant neural crest-derived sympathetic ganglia and dorsal root ganglia were unaffected. We hypothesize that loss of normal coordinated signaling from the notochord, foregut, and somites underlies the diminished survival of the neural crest lineage within Patch mutants resulting in subsequent neural crest-deficient phenotypes.     

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.     

Cell division in the ciliary ganglion of quail embryos in situ and after back-transplantation into the neural crest migration pathways of chick embryos

Embryonic 4- to 15-day-old quail ciliary ganglia (CG) were grafted into the neural crest migration pathway of 2-day-old chick embryos at the adrenomedullary level of the neural axis. This back-transplantation results in dispersion of cells of the implanted ganglion, their migration in the host embryo, and subsequent promotion of their differentiation into a variety of neural-crest-derived cell types including adrenergic cells of the sympathetic ganglia and adrenal medulla. These cells can be recognized in the host through the nuclear marker that they carry. Here, we have analyzed quantitatively the expansion of CG-derived cell population after the graft, and compared cell division in CG after back-transplantation and during normal in situ development over the same period of time. Tritiated-thymidine [( 3H]TdR) incorporation showed that grafted CG cells proliferated during their migration and, to a greater extent, after they had homed to the host structures. Furthermore, proliferative activity of quail cells in the graft was found to be significantly higher than the growth rate of the CG cells in situ during the same period of development. In the quail donor embryo, the birthdate of the CG neurons occurred early in development; from 6 days onward, only nonneuronal cells were still dividing. When back-transplanted, the 4- to 5-day-old CG provided numerous quail cells located in autonomic structures of the host embryo. However, this increase of the total quail cell population and of cell division was reduced when CG were taken from quail donors at progressively later developmental stages. Postmitotic neurons from mature CG were found not to survive under the graft conditions. It is proposed that back-transplantation of the CG stimulates cell division and modifies the developmental programme of still undifferentiated precursor cells which then can give rise to a variety of cell types belonging either to the glial or the autonomic nerve and paraganglionic cell phenotypes, to the exclusion of sensory neurons which never derive from CG grafts.     

Consequences of somite manipulation on the pattern of dorsal root ganglion development

We have investigated dorsal root ganglion formation, in the avian embryo, as a function of the composition of the paraxial somitic mesoderm. Three or four contiguous young somites were unilaterally removed from chick embryos and replaced by multiple cranial or caudal half-somites from quail embryos. Migration of neural crest cells and formation of DRG were subsequently visualized both by the HNK-1 antibody and the Feulgen nuclear stain. At advanced migratory stages (as defined by Teillet et al. Devl Biol. 120, 329-347 1987), neural crest cells apposed to the dorsolateral faces of the neural tube were distributed in a continuous, nonsegmented pattern that was indistinguishable on unoperated sides and on sides into which either half of the somites had been grafted. In contrast, ventrolaterally, neural crest cells were distributed segmentally close to the neural tube and within the cranial part of each normal sclerotome, whereas they displayed a nonsegmental distribution when the graft involved multiple cranial half-somites or were virtually absent when multiple caudal half-somites had been implanted. In spite of the identical dorsal distribution of neural crest cells in all embryos, profound differences in the size and segmentation of DRG were observed during gangliogenesis (E4-9) according to the type of graft that had been performed. Thus when the implant consisted of compound cranial half-somites, giant, coalesced ganglia developed, encompassing the entire length of the graft. On the other hand, very small, dorsally located ganglia with irregular segmentation were seen at the level corresponding to the graft of multiple caudal half-somites. We conclude that normal morphogenesis of dorsal root ganglia depends upon the craniocaudal integrity of the somites.