Plasticity and rigidity of differentiation of brain vesicles studied in quail-chick chimeras

Transplantation of a piece of the alar plate of the prosencephalon or of the rhombencephalon of quail embryos into the roof of the mesencephalon of chick embryos was carried out at 7-10 somite stage. Results obtained were: the transplanted alar plate of the prosencephalon differentiated into tissue closely resembling the tectum when the transplants were integrated into the host mesencephalon; in all the cases, the alar plate of the rhombencephalon did not differentiate into tectum-like structure, but into rhombencephalic descendants. We conclude that the alar plate of the prosencephalon at 7-10 stage is not definitively determined and may retain an ability to differentiate into the optic tectum, whereas the prospective fate of the rhombencephalon has already been determined at 7-10 stage.     

Developing nervous tissue induces formation of blood-brain barrier characteristics in invading endothelial cells: A study using quail-chick transplantation chimeras

Brain capillaries have structural and functional characteristics that constitute a regulatory interface, or “barrier,” between the blood and the brain. We have investigated the role of the neural tissue environment in the differentiation of the endothelial barrier, by transplanting embryonic brain fragments to the coelomic cavity, where they were vascularized by nonneural vessels, and fragments of embryonic mesoderm to the brain, where they were vascularized by neural vessels. A major problem in this approach is that when embryonic tissues are transplanted to an ectopic site, their own blood vessels survive and form a part of the new vascular system. This has made the results of previous experiments difficult to interpret. We overcame this problem by transplanting fragments of tissue that had not yet been vascularized from very young quail embryos to host chick embryos. These grafts did not contain vascular channels that could form part of a new vascular system. Furthermore, the distinctive quail nuclear morphology allowed us to demonstrate that the grafted tissue was, in fact, vascularized by the host vessels. Abdominal vessels vascularizing grafted neural tissue formed structural, functional, and histochemical features of the blood-brain barrier. In contrast, brain vessels vascularizing grafted mesodermal tissue were devoid of barrier characteristics. These results indicate that endothelial blood-brain barrier characteristics develop in response to some aspect of the neural environment.     

A study of the development of the hemopoietic system using quail-chick chimeras obtained by blastoderm recombination

The anterior part of the area pellucida from quail blastoderms extending to the 10th or the 17th somite level was substituted for the corresponding region of chick blastoderms in ovo. Reciprocal grafts were also carried out. In external appearance the resulting chimeras had a composite body, one species contributing the head and neck or the head, neck, and wing regions while the other species provided the remainder. The chimeras were always grafted on a chick yolk sac. The cellular composition of hemopoietic organs according to species was analyzed by means of the quail-chick nuclear difference, in 39 viable chimeras at 11–13 days of incubation. The thymus composition depended on the level of the boundary between the two species. In chimeras in which the quail contributed head and neck, the thymic epithelial stroma was made of quail cells while the lymphoid population was of chick origin. In contrast, when the quail contribution also extended to the wings, both thymic stroma and lymphoid cells were of quail origin. In reciprocal combinations, in which head and neck were of chicken origin on a quail body, a different result was obtained: no lymphoid cells were present in the thymus which was reduced to its epithelial component and this was of chick origin. On the other hand, if the chick contribution extended to the wings, as in the reciprocal combination, all thymus components were of chick origin. The spleen and the bursa of Fabricius in most instances did not differ in their cellular composition from the surrounding tissues; however in some chimeras a minor admixture of cells of the other species was also found. Overall these results suggest that hemopoietic stem cells destined to colonize intraembryonic organs arise in territories derived from the whole area pellucida excluding the prospective head-neck region. Furthermore, each hemopoietic organ rudiment appears to be colonized by precursors derived from adjacent territories.     

Temporospatial study of the migration and distribution of cardiac neural crest in quail-chick chimeras.

It has been demonstrated that the septation of the outflow tract of the heart is formed by the cardiac neural crest. Ablation of this region of the neural crest prior to its migration from the neural fold results in anomalies of the outflow and inflow tracts of the heart and the aortic arch arteries. The objective of this study was to examine the migration and distribution of these neural crest cells from the pharyngeal arches into the outflow region of the heart during avian embryonic development. Chimeras were constructed in which each region of the premigratory cardiac neural crest from quail embryos was implanted into the corresponding area in chick embryos. The transplantations were done unilaterally on each side and bilaterally. The quail-chick chimeras were sacrificed between Hamburger-Hamilton stages 18 and 25, and the pharyngeal region and outflow tract were examined in serial paraffin sections to determine the distribution pattern of quail cells at each stage. The neural crest cells derived from the presumptive arch 3 and 4 regions of the neuraxis occupied mainly pharyngeal arches 3 and 4 respectively, although minor populations could be seen in pharyngeal arches 2 and 6. The neural crest cells migrating from the presumptive arch 6 region were seen mainly in pharyngeal arch 6, but they also populated pharyngeal arches 3 and 4. Clusters of quail neural crest cells were found in the distal outflow tract at stage 23.     

The early development of cranial sensory ganglia and the potentialities of their component cells studied in quail-chick chimeras

The quail-chick marker system has been used to study the early developmental stages of the ganglia located along cranial nerves VII, IX, and X. The streams of neural crest cells arising from the rhombencephalic-vagal neural crest were followed from the onset of their migration up to the localization of crest cells in the trunk and root ganglia of these nerves. It was shown that two different populations of crest cells are segregated early as a result of morphogenetic movements in the hypobranchial region. The dorsal population gives rise to the root ganglia of nerves IX and X located close to the encephalic vesicles, where the crest cells differentiate both into neurons and into glia. In contrast, the ventral stream of neural crest cells contributes together with cells from epibranchial placodes to the trunk ganglia (geniculate, petrous, and nodose ganglia) of cranial nerves VII, IX, and X. The successive steps of the invasion of the placodal anlage by crest cells can be followed owing to the selective labeling of the neural crest cells. It appears that the latter give rise to the satellite cells of the geniculate, petrous, and nodose ganglia while the large sensory neurons originate from the placodes. The nodose ganglion has been the subject of further studies aimed to investigate whether neuronal potentialities can be elicited in the neural crest-derived cells that it contains. The ability to label selectively either the neurons or the glia by the quail nuclear marker made this investigation possible in the particular case of the nodose ganglion whose neurons and satellite cells have a different embryonic origin. By the technique already described (N. M. Le Douarin, M. A. Teillet, C. Ziller, and J. Smith, 1978, Proc. Nat. Acad. Sci. USA75, 2030–2034) of back-transplantation into the neural crest migration pathway of a younger host, it was shown that the presumptive glial cells of the nodose ganglion are able to remigrate when transplanted into a 2-day chick host and to differentiate into autonomic structures (sympathetic ganglion cells, adrenomedullary cells, and enteric ganglia). It is proposed as a working hypothesis that neuronal potentialities contained in the neural crest cells which invade the placodal primordium of the nodose ganglion are repressed through cell-cell interactions occurring between placodal and crest cells.     

Mediolateral somitic origin of ribs and dermis determined by quail-chick chimeras

Somites are transient mesodermal structures giving rise to all skeletal muscles of the body, the axial skeleton and the dermis of the back. Somites arise from successive segmentation of the presomitic mesoderm (PSM). They appear first as epithelial spheres that rapidly differentiate into a ventral mesenchyme, the sclerotome, and a dorsal epithelial dermomyotome. The sclerotome gives rise to vertebrae and ribs while the dermomyotome is the source of all skeletal muscles and the dorsal dermis. Quail-chick fate mapping and diI-labeling experiments have demonstrated that the epithelial somite can be further subdivided into a medial and a lateral moiety. These two subdomains are derived from different regions of the primitive streak and give rise to different sets of muscles. The lateral somitic cells migrate to form the musculature of the limbs and body wall, known as the hypaxial muscles, while the medial somite gives rise to the vertebrae and the associated epaxial muscles. The respective contribution of the medial and lateral somitic compartments to the other somitic derivatives, namely the dermis and the ribs has not been addressed and therefore remains unknown. We have created quail-chick chimeras of either the medial or lateral part of the PSM to examine the origin of the dorsal dermis and the ribs. We demonstrate that the whole dorsal dermis and the proximal ribs exclusively originates from the medial somitic compartment, whereas the distal ribs derive from the lateral compartment.     

The developmental fate of the cephalic mesoderm in quail-chick chimeras.

The developmental fate of the cephalic paraxial and prechordal mesoderm at the late neurula stage (3-somite) in the avian embryo has been investigated by using the isotopic, isochronic substitution technique between quail and chick embryos. The territories involved in the operation were especially tiny and the size of the transplants was of about 150 by 50 to 60 microns. At that stage, the neural crest cells have not yet started migrating and the fate of mesodermal cells exclusively was under scrutiny. The prechordal mesoderm was found to give rise to the following ocular muscles: musculus rectus ventralis and medialis and musculus oblicus ventralis. The paraxial mesoderm was separated in two longitudinal bands: one median, lying upon the cephalic vesicles (median paraxial mesoderm--MPM); one lateral, lying upon the foregut (lateral paraxial mesoderm--LPM). The former yields the three other ocular muscles, contributes to mesencephalic meninges and has essentially skeletogenic potencies. It contributes to the corpus sphenoid bone, the orbitosphenoid bone and the otic capsules; the rest of the facial skeleton is of neural crest origin. At 3-somite stage, MPM is represented by a few cells only. The LPM is more abundant at that stage and has essentially myogenic potencies with also some contribution to connective tissue. However, most of the connective cells associated with the facial and hypobranchial muscles are of neural crest origin. The more important result of this work was to show that the cephalic mesoderm does not form dermis. This function is taken over by neural crest cells, which form both the skeleton and dermis of the face. If one draws a parallel between the so-called "somitomeres" of the head and the trunk somites, it appears that skeletogenic potencies are reduced in the former, which in contrast have kept their myogenic capacities, whilst the formation of skeleton and dermis has been essentially taken over by the neural crest in the course of evolution of the vertebrate head.     

Cellular dynamics and molecular control of the development of organizer-derived cells in quail-chick chimeras

Malformations affecting the nervous system in humans are numerous and various in etiology. Many are due to genetic deficiencies or mechanical accidents occurring at early stages of development. It is thus of interest to reproduce such human malformations in animal models. The avian embryo is particularly suitable for researching the role of morphogenetic movements and genetic signaling during early neurogenesis. The last ten years of research with Nicole Le Douarin in the Nogent Institut have brought answers to questions formulated by Etienne Wolff at the beginning of his career, by showing that Hensen's node, the avian organizer, is at the source of all the midline cells of the embryo and ensures cell survival, growth and differentiation of neural and mesodermal tissues.     

Mapping of the early neural primordium in quail-chick chimeras : I. Developmental relationships between placodes, facial ectoderm, and prosencephalon

Defined fragments of the anterolateral neural ridge and of the associated region of the neural plate of presomitic to three-somite stage quail embryos were grafted isotopically and isochronically into chick hosts. This resulted in the development of apparently normal brain and facial structures to which the contribution of the grafted tissue could be observed by means of the quail nuclear marker. It was shown that the anterolateral neural ridge contains the progenitor cells of the adenohypophyseal and olfactory placodes and also of the superficial ectoderm lining the nasal cavity and conchae and the superficial ectoderm of the beak. When the appropriate region of the neural ridge was involved in the quail-chick substitution, the egg tooth was made up of graft-derived cells. Grafting of the neural plate area adjacent to the "ridge" territory containing the placodal ectoderm revealed that the presumptive region of the hypothalamus is in contiguity with that of the adenohypophyseal placode. The same observation was made for the olfactory placode and the floor of the telencephalon from which the olfactive bulb later develops.     

A balance of BMP and notch activity regulates neurogenesis and olfactory nerve formation

Although the function of the adult olfactory system has been thoroughly studied, the molecular mechanisms regulating the initial formation of the olfactory nerve, the first cranial nerve, remain poorly defined. Here, we provide evidence that both modulated Notch and bone morphogenetic protein (BMP) signaling affect the generation of neurons in the olfactory epithelium and reduce the number of migratory neurons, so called epithelioid cells. We show that this reduction of epithelial and migratory neurons is followed by a subsequent failure or complete absence of olfactory nerve formation. These data provide new insights into the early generation of neurons in the olfactory epithelium and the initial formation of the olfactory nerve tract. Our results present a novel mechanism in which BMP signals negatively affect Notch activity in a dominant manner in the olfactory epithelium, thereby regulating neurogenesis and explain why a balance of BMP and Notch activity is critical for the generation of neurons and proper development of the olfactory nerve.     

Chagas' disease parasite promotes neuron survival and differentiation through TrkA nerve growth factor receptor

TrkA is a receptor tyrosine kinase activated primarily by nerve growth factor (NGF) to regulate differentiation, survival, and other important functions of neurons. Given the critical role TrkA plays in neural maintenance, it may be that microbial invaders of the nervous system utilize this receptor to reduce tissue damage for maximizing host-parasite equilibrium. Candidate pathogens could be those, like Trypanosoma cruzi, which may produce relatively little brain or nerve damage in long-lasting infections. We show here that T. cruzi, via its neuraminidase, binds TrkA in a NGF-inhibitable manner, induces TrkA autophosphorylation, and, through TrkA-dependent mechanisms, triggers phosphatidylinositol 3-kinase (PI3K)/Akt kinase signaling, cell survival, and neurite outgrowth. Unlike NGF, the neuraminidase does not react with the apoptosis-causing pan-neurotrophin receptor p75NTR. Therefore, these studies identify a novel and unique TrkA ligand in a microbial invader of the nervous system, raising the thus far unsuspected prospect of TrkA underlying clinical progression of an important human infectious disease.     

Analysis of neurogenesis in a mammalian neuroepithelium: proliferation and differentiation of an olfactory neuron precursor in vitro

Development of a culture system for mammalian olfactory epithelium has permitted the process of neurogenesis to be examined in vitro. Antibody markers allowing the unambiguous identification of putative neuroepithelial stem cells (keratin+ basal cells) and differentiated neurons (N-CAM+ olfactory receptor neurons) are described. In combination with [3H]thymidine uptake analysis, these antibodies have been used to characterize the existence, proliferation, and differentiation of the immediate neuronal precursor in this system. This cell is distinct from basal cells and rapidly sorts out from them, dividing as it migrates. Data are presented which suggest that the precursor follows a simple lineage program, dividing to give rise to two N-CAM+ daughter neurons. Although this precursor efficiently generates neurons in defined medium, neurogenesis subsequently ceases because new precursors are not produced, suggesting that epigenetic factors may regulate continual neurogenesis in this system.     

Acetylcholine synthesis and neuron differentiation

Development of the nervous system is dependent on the co-operation between cell determination events and the action of epigenetic factors; in addition to well known factors, e.g. growth factors, neurotransmitters have been assigned a role as "morphogens" and modulators of neuronal differentiation in an early developmental phase. The possible role of acetylcholine as a modulator of neuronal differentiation has been considered in two experimental systems. A neuroblastoma cell line, which does not synthesise any neurotransmitter, has been transfected with a choline acetyltransferase construct; activation of acetylcholine synthesis, thus achieved, is followed by a higher expression of neuronal specific traits. The presence in these cells of muscarinic receptors is consistent with the existence of an autocrine loop, which may be responsible for the more advanced differentiation state observed in the transfected cells. Expression of cholinergic markers appears as a common feature of DRG sensory neurons, independently of the neurotransmitter used. Choline acetyltransferase can be detected in DRG at early developmental stages. The distribution of muscarinic receptors in DRG has suggested that activation of acetylcholine synthesis may be related in an early developmental phase to the interaction between neurons and nonneuronal cells and to modulation of cell differentiation. Both systems suggest that acetylcholine may have a role as a modulator of neuronal differentiation.     

Mapping of the early neural primordium in quail-chick chimeras. II. The prosencephalic neural plate and neural folds: implications for the genesis of cephalic human congenital abnormalities

Mapping of the avian neural primordium was carried out at the early somitic stages by substituting definite regions of the chick embryo by their quail counterpart. The quail nuclear marker made it possible to identify precisely the derivatives of the grafted areas within the chimeric cephalic structures. A fate map of the prosencephalic neural plate and neural folds is presented. Moreover the origin of the forebrain meninges from the pro- and mesencephalic neural crest is demonstrated. In the light of the data resulting from these experiments, we present a rationale for the genesis of malformations of the face and brain and of congenital endocrine abnormalities occurring in man.     

Analysis of causes for formation of chimeras

The present study investigated cDNA chimeras using two closely related members of the rice secretory protein gene family as an example. The chimeras detected in initial cDNA products that were amplified using LA Taq polymerase involved two categories: single-site type and multiple-site type with the frequency being about 20% and 3%, respectively. Further investigation revealed that PCR buffer additives and type of DNA polymerase had a major effect on the formation of chimeras in mixed-template amplification. Heteroduplex repair by microbial DNA repair systems in cDNA cloning was confirmed to produce the chimeras too, but it was not the major source.     

Evolution of the lumbo-sacral neural crest in the avian embryo: Origin and differentiation of the ganglionated nerve of Remak studied in interspecific quail-chick chimaerae

Summary Isotopic and isochronic transplantation of fragments of quail neural tube into chick demonstrates that neural and glial cells of the entire ganglion of Remak (RG) arise from the lumbo-sacral level of the neural crest.The ganglioblasts first accumulate in the mesorectum (stage 24 of Hamburger and Hamilton, in the chick and I8 of Zacchei in the quail) and subsequently migrate cranially.Histochemical studies have been carried out on the rectal and cloacal parts of the quail RG at various stages of development. Cholinesterase activity can be detected as soon as the primordium is in place and the intensity of the reaction increases rapidly. During morphogenesis of the cloacal region the RG and the pelvic plexus become intimately associated. Catecholamine-containing cells are found first in the pelvic plexus, then in the cloacal part of the RG. Fluorescent cells are often grouped close to blood vessels and associated with non-fluorescent ganglia. Cranial to the level of the bursa of Fabricius, the RG is composed only of non-fluorescent neurons whatever the developmental stage considered (up to 1 day after hatching).The developmental capabilities of the RG of the 5-day quail have been tested by transplanting various parts of the hind-gut with the dorsal mesentery onto the chorio-allantoic membrane. Catecholamine-containing cells develop only in grafts including the cloacal region.By using quail-chick chimaerae in which the RG belongs to the quail while mesentery and gut are of chick origin, it was possible to show that neurons which develop in the graft (i.e. in the absence of preganglionic innervation), send nerve fibres into the gut wall. Moreover some neuroblasts located in the primordium of the RG migrate into the gut wall and give rise to some enteric ganglion cells. The contribution of the lumbo-sacral neural crest to the enteric ganglia, by this route, is discussed.List of Abbreviations in Text FIF formol-induced fluorescence - H & H Hamburger and Hamilton - Z Zacchei - CAM chorio-allantoic membrane - SIF small intensely fluorescent (cells)