In vitro stimulation of cartilage in embryonic chick neural crest cells by products of rentinal pigmented epithelium.

The retinal pigmented epithelium of the chick embryo influences head neural crest mesenchymal cells to form the scleral cartilage of the eye. The possible role of extracellular matrix in this interaction was studied. Extracellular matrix was deposited on Millipore filters in vitro by pigmented epithelial cells which were then killed by distilled water lysis. When grown on the Millipore filters which had carried pigmented epithelium, clonal neural crest and periocular mesenchyme “target” cells formed cartilage in 61 of 155 experiments. Cartilage was not formed when the cells were grown on naked filters nor did gels of purified Type I and Type II collagen promote chondrogenesis. It is concluded that extracellular matrix deposited by the pigmented epithelium in vitro is a potent stimulus for the induction of chondrogenesis in competent mesenchyme, and that living pigmented epithelial cells need not be present for such induction.     

Melanocyte-stimulating hormone affects melanogenic differentiation of quail neural crest cells in vitro

Quail neural crest cells were treated in vitro with alpha-melanocyte-stimulating hormone (alpha-MSH) or dibutyryl cyclic AMP (dbcAMP) plus theophylline. These treatments increased the proportion of melanocytes to total cells in crest cell outgrowth cultures. Pigmentation of neural crest cell clusters proceeded more rapidly when cultures were treated with alpha-MSH or dbcAMP plus theophylline than when untreated. In clonal cell cultures, the proportion of pigmented colonies to total colonies was increased by MSH treatment. From these results, MSH seems not only to accelerate melanogenic differentiation but also to affect the state of commitment of neural crest cells to melanogenic differentiation in vitro, and this action of MSH appears to be mediated by cAMP.     

Possible demonstration of multipotential nature of embryonic neural retina by clonal cell culture.

The possible multipotential nature of the neural retina of early chick embryos was examined by the technique of clonal cell culture. Cultures were prepared from cells dissociated from freshly excised neural retinas of 3.5-day-old chick embryos or from cells harvested from primary highdensity cultures. The following four colony types were obtained: colonies differentiating into “lentoid bodies”; colonies with pigment cells; colonies with both “lentoid bodies” and pigment cells; and colonies comprised entirely of unidentifiable cells. Neuronal differentiation occurred frequently in the early stages of culture (up to about 10 days). In some of these neuronal colonies, “lentoid bodies” and, rarely, both “lentoid bodies” and pigment cells differentiated after a further culture period of up to 30 days. Secondary colonies established from primary colonies after 9–10 days demonstrated that these original colonies fell into four different categories: those giving rise to secondary colonies containing only “lentoid bodies,” those giving rise to pigmented colonies only, those developing both lentoid and pigmented colonies, and finally those which gave rise to secondary colonies of all three types, lentoid, pigmented, and mixed colonies. When primary pigmented colonies were recloned at about 30 days after inoculation, the differentiated pigment cells transdifferentiated into lens. Whether multispecific colonies were really of clonal origin or not is discussed. The possible presence of a multipotent progenitor cell able to give rise to multispecific clones in the neural retina of 3.5-day-old chick embryos is suggested. A sequence of differentiation starting from multipotent neural retinal cells to be terminated with lens through the differentiation of neuronal and pigment cells is hypothetically proposed.     

Tumor-Promoting Phorbol Esters Promote Melanogenesis and Prevent Expression of the Adrenergic Phenotype in Quail Neural Crest Cells

Tumor-promoting phorbol esters were used to manipulate the in vitro development of neural crest cells. When plated at clonal density in secondary culture, quail neural crest cells from the trunk region gave rise to three types of colonies, pigmented, unpigmented, and mixed. Pigmented colonies consisted exclusively of melanocytes; up to 50% of the unpigmented and mixed colonies contained adrenergic nerve cells which could be identified by a catecholamine-specific histofluorescence method. Addition of potent tumor promoters to the culture medium shortened the doubling time of neural crest cells and altered their morphologic appearance. It also delayed the onset of pigmentation, prevented the expression of the adrenergic phenotype, reduced the number of unpigmented and mixed colonies, and increased the number of pigmented colonies, most likely by directing progenitor cells preferentially to the melanogenic pathway. There was a clear correlation between the ability of phorbol esters to promote skin tumors in mice and their ability to interfere with the in vitro development of quail neural crest cells. The potent promoters 12–0–tetradecanoyl phorbol 13–acetate (TPA) and phorbol 12,13–didecanoate (PDD) were most effective, phorbol 12,13–diacetate (PDA) was considerably less effective, the nonpromoting analogues 4–0–methyl 12–0–tetradecanoyl phorbol 13–acetate (4–0–Me-TPA) and 4α-phorbol 12,13–didecanoate (4α-PDD) and the parent alcohol phorbol (PHR) had little or no effect.     

Establishment of the scleral cartilage in the chick.

This study was undertaken to investigate the establishment of the scleral cartilage in the chick embryo. Johnston et al. (1974) has demonstrated that most of the cells of the scleral cartilage originate in the cranial neural crest. By means of a series of chorioallantoic grafts of pigmented retina, and its adherent periocular mesenchyme from stage 11 to 25, the present experiments show that the cranial neural crest cells arrive at the eye in sufficient numbers to form cartilage by stage 14. Pigmented retina, denuded of mesenchyme, from stage 16 embryos implanted into the head of stage 13 embryos induces cartilage formation in head mesenchyme. However, neither pigmented retina nor spinal cord could induce cartilage formation in chorioallantoic mesenchyme. Combination grafts of cranial neural crest and presumptive optic vesicle developed neural tissue, pigmented retina, and in some cases sclera-like cartilage. Thus, periorbital mesenchyme, derived largely from cranial neural crest, at about stage 14 develops the scleral cartilage in response to induction by the pigmented retina.     

Clonal identification of multipotent precursors from adult mouse pancreas that generate neural and pancreatic lineages

The clonal isolation of putative adult pancreatic precursors has been an elusive goal of researchers seeking to develop cell replacement strategies for diabetes. We report the clonal identification of multipotent precursor cells from the adult mouse pancreas. The application of a serum-free, colony-forming assay to pancreatic cells enabled the identification of precursors from pancreatic islet and ductal populations. These cells proliferate in vitro to form clonal colonies that coexpress neural and pancreatic precursor markers. Upon differentiation, individual clonal colonies produce distinct populations of neurons and glial cells, pancreatic endocrine beta-, alpha- and delta-cells, and pancreatic exocrine and stellate cells. Moreover, the newly generated beta-like cells demonstrate glucose-dependent Ca(2+) responsiveness and insulin release. Pancreas colonies do not express markers of embryonic stem cells, nor genes suggestive of mesodermal or neural crest origins. These cells represent a previously unidentified adult intrinsic pancreatic precursor population and are a promising candidate for cell-based therapeutic strategies.     

Migration and proliferation of cultured neural crest cells in W mutant neural crest chimeras.

Chimeric mice, generated by aggregating preimplantation embryos, have been instrumental in the study of the development of coat color patterns in mammals. This approach, however, does not allow for direct experimental manipulation of the neural crest cells, which are the precursors of melanoblasts. We have devised a system that allows assessment of the developmental potential and migration of neural crest cells in vivo following their experimental manipulation in vitro. Cultured C57Bl/6 neural crest cells were microinjected in utero into neurulating Balb/c or W embryos and shown to contribute efficiently to pigmentation in the host animal. The resulting neural crest chimeras showed, however, different coat pigmentation patterns depending on the genotype of the host embryo. Whereas Balb/c neural crest chimeras showed very limited donor cell pigment contribution, restricted largely to the head, W mutant chimeras displayed extensive pigmentation throughout, often exceeding 50% of the coat. In contrast to Balb/c chimeras, where the donor melanoblasts appeared to have migrated primarily in the characteristic dorsoventral direction, in W mutants the injected cells appeared to migrate in the longitudinal as well as the dorsoventral direction, as if the cells were spreading through an empty space. This is consistent with the absence of a functional endogenous melanoblast population in W mutants, in contrast to Balb/c mice, which contain a full complement of melanocytes. Our results suggest that the W mutation disturbs migration and/or proliferation of endogenous melanoblasts. In order to obtain information on clonal size and extent of intermingling of donor cells, two genetically marked neural crest cell populations were mixed and coinjected into W embryos. In half of the tricolored chimeras, no co-localization of donor crest cells was observed, while, in the other half, a fine intermingling of donor-derived colors had occurred. These results are consistent with the hypothesis that pigmented areas in the chimeras can be derived from extensive proliferation of a few donor clones, which were able to colonize large territories in the host embryo. We have also analyzed the development of pigmentation in neural crest cultures in vitro, and found that neural tubes explanted from embryos carrying wt or weak W alleles produced pigmented melanocytes while more severe W genotypes were associated with deficient pigment formation in vitro.     

Clonal analysis of quail neural crest cells: They are pluripotent and differentiate in vitro in the absence of noncrest cells

To determine if neural crest cells are pluripotent and establish whether differentiation occurs in the absence of noncrest cells, a cell culture method was devised in which differentiation could be examined in clones derived from single, isolated neural crest cells. Single neural crest cells, which were isolated before the onset of in vivo migration, gave rise to three types of clones: pigmented, unpigmented, and mixed. Pigmented clones consisted of melanocytes only, whereas some unpigmented cells in mixed and unpigmented clones contained catecholamines, identifying them as adrenergic cells. Extracellular matrix derived from quail somite or chick skin fibroblast cultures stimulated adrenergic differentiation and axon formation. These results demonstrate for the first time the existence of pluripotent quail neural crest cells that give rise to at least two progeny, melanocytes and neuronal cells. They also suggest that continuous direct interactions with noncrest cells are not required for the differentiation of these two cell types. However, components of the extracellular matrix derived from noncrest cells may play an important role in expression of the adrenergic phenotype.     

Invasive characteristics of neural crest cells in vitro

An investigation of the invasiveness of avian neural crest cells and neural crest-derived melanocytes through a human amniotic basement membrane (BM) was undertaken. Avian neural tube explants or derived melanocyte populations were seeded directly onto BMs in membrane invasion culture system (MICS) chambers for periods of 24, 48, and 72 h. In 36 experimental trials for each group, neither neural crest nor neural crest-derived melanocytes were observed to have invaded the BMs. In concert with these studies, coculturing of B16F10 murine melanoma cells with avian neural crest-derived melanocytes was performed in MICS chambers. Under these experimental conditions, the neural crest-derived melanocytes were able to successfully invade the BMs and to a greater extent than the B16F10 tumor cells. These data suggest that neural crest cells and neural crest-derived melanocytes do not have the ability to invade the BM alone; however, they can be induced to be invasive when cocultured in the presence of B16F10 cells. Alternatively, the B16F10 cells may create weaknesses within the BM that facilitate migration of the pigmented crest cells.     

Differentiation of neural crest cells of Xenopus laevis in clonal culture

Clonal cultures were performed with the use of neural crest cells and their derivatives, chromatophores, from Xenopus laevis in order to elucidate the state of commitment in early embryogenesis. Neural crest cells that outgrew from neural tube explants were isolated and plated at clonal density. Cloned neural crest cells differentiated and gave rise to colonies that consisted of 1) only melanophores, 2) only xanthophores, or 3) melanophores and xanthophores. Xanthophores and iridophores, which differentiated in vitro, were also isolated and cloned. Cloned xanthophores proliferated in a stable fashion and did not lose their properties. On the other hand, cloned iridophores converted into melanophores as they proliferated. These results suggest that there is heterogeneity in the state of commitment of neural crest cells immediately after migration with regard to chromatophore differentiation and that iridophore determination is relatively labile (at least in vitro), whereas melanophore and xanthophore phenotypes are stable.     

In vitro clonal analysis of quail cardiac neural crest development

The developmental potentials of cardiac neural crest cells were investigated by in vitro clonal analysis. Five morphologically distinct types of clones were observed: (1) "pigmented" clones contained melanocytes only; (2) "mixed" clones consisted of pigmented and unpigmented cells; (3) "unpigmented dense" clones consisted of flattened, closely aligned unpigmented cells; (4) "unpigmented loose" clones consisted of a few loosely arranged, flattened cells; and (5) "unpigmented large" clones included a large number of small, stellate cells that were highly proliferative. The binding patterns of antibodies against lineage-specific markers showed that cells in the different clones expressed characteristic phenotypes. The following phenotypes were expressed in addition to pigment cells: smooth muscle cells, connective tissue cells, chondrocytes, and cells in the sensory neuron lineage. Mixed clones expressed all five phenotypes. Unpigmented dense clones contained smooth muscle cells, connective tissue cells, chondrocytes, and sensory neurons. Unpigmented loose clones exclusively consisted of smooth muscle cells, whereas unpigmented large clones contained chondrocytes and sensory neuron precursors. Based on these results, the following conclusions can be drawn: (1) Pigmented and unpigmented loose clones are most likely formed by precursors that are committed to the melanogenic and myogenic cell lineages, respectively. (2) Mixed and unpigmented dense clones are derived from pluripotent cells with the capacity to give rise to four or five phenotypes. (3) Unpigmented large clones originate from progenitor cells that appear to have a partially restricted developmental potential, that is, these cells are capable of generating two phenotypes in clonal cultures. Thus, the data indicate that the early migratory cardiac neural crest is a heterogeneous population of cells, consisting of pluripotent cells, cells with a partially restricted developmental potential, and cells committed to a particular cell lineage.     

Isolation of Retinal Stem Cells from the Mouse Eye

The adult mouse retinal stem cell (RSC) is a rare quiescent cell found within the ciliary epithelium (CE) of the mammalian eye^1,2,3. The CE is made up of non-pigmented inner and pigmented outer cell layers, and the clonal RSC colonies that arise from a single pigmented cell from the CE are made up of both pigmented and non-pigmented cells which can be differentiated to form all the cell types of the neural retina and the RPE. There is some controversy about whether all the cells within the spheres all contain at least some pigment⁴; however the cells are still capable of forming the different cell types found within the neural retina^1-3. In some species, such as amphibians and fish, their eyes are capable of regeneration after injury⁵, however; the mammalian eye shows no such regenerative properties. We seek to identify the stem cell in vivo and to understand the mechanisms that keep the mammalian retinal stem cells quiescent^6-8, even after injury as well as using them as a potential source of cells to help repair physical or genetic models of eye injury through transplantation^9-12. Here we describe how to isolate the ciliary epithelial cells from the mouse eye and grow them in culture in order to form the clonal retinal stem cell spheres. Since there are no known markers of the stem cell in vivo, these spheres are the only known way to prospectively identify the stem cell population within the ciliary epithelium of the eye.     

Altered neuronal lineages in the facial ganglia of Hoxa2 mutant mice

Neurons of cranial sensory ganglia are derived from the neural crest and ectodermal placodes, but the mechanisms that control the relative contributions of each are not understood. Crest cells of the second branchial arch generate few facial ganglion neurons and no vestibuloacoustic ganglion neurons, but crest cells in other branchial arches generate many sensory neurons. Here we report that the facial ganglia of Hoxa2 mutant mice contain a large population of crest-derived neurons, suggesting that Hoxa2 normally represses the neurogenic potential of second arch crest cells. This may represent an anterior transformation of second arch neural crest cells toward a fate resembling that of first arch neural crest cells, which normally do not express Hoxa2 or any other Hox gene. We additionally found that overexpressing Hoxa2 in cultures of P19 embryonal carcinoma cells reduced the frequency of spontaneous neuronal differentiation, but only in the presence of cotransfected Pbx and Meis Hox cofactors. Finally, expression of Hoxa2 and the cofactors in chick neural crest cells populating the trigeminal ganglion also reduced the frequency of neurogenesis in the intact embryo. These data suggest an unanticipated role for Hox genes in controlling the neurogenic potential of at least some cranial neural crest cells.     

Generation of pigmented stripes in albino mice by retroviral marking of neural crest melanoblasts.

The pigment cells of the skin are derived from melanoblasts which originate in the neural crest. The dorsoventral migration of melanoblasts has been visualized in pigment stripes seen in aggregation chimeras, and the width of these bands has suggested that the entire pigmentation of the coat is derived from a small number of founder cells. We have generated mosaic mice by marking single melanoblasts in utero to gain information on the clonal history of pigment-forming cells. A retroviral vector carrying the human tyrosinase gene was constructed and microinjected into neurulating albino mouse embryos. Albino mice are devoid of pigmentation due to deficiency of tyrosinase. Thus, transduction of the wild-type gene into the otherwise normal melanoblasts should rescue the mutant phenotype, giving rise to patches of pigmentation, which correspond to the area colonized by the mitotic progeny of a marked clone. Mosaic animals derived from the injected embryos indeed showed pigmented bands with a width strikingly similar to the 'standard' stripes seen in aggregation chimeras. These results are consistent with the notion that the unit width bands seen in aggregation chimeras represent the clonal progeny of a single melanoblast and verify Mintz's (1967) conclusion that a few founder melanoblasts give rise to coat pigmentation. The pigment cells of the eye are of dual origin: the melanocytes in choroid and outer layer of the iris are derived from the neural crest and those in the pigment layer of the retina from the neuroepithelium of the optic cup. Marked clones in both lineages were observed in the eyes of many mosaic animals.     

Effect of lectins and sugars on primary sperm attachment in the horseshoe crab, Limulus polyphemus L

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.     

The early migration of neural crest cells in the trunk region of the avian embryo: an electron microscopic study

Four phases of neural crest migration characteristic of early avian trunk regions are described: (a) appearance, during which crest cells reside in the dorsal neural tube, but are separated from each other dorsally by large spaces; (b) condensation, during which large spaces between the crest cells become reduced, the cells elongate, flatten upon the surface of the neural tube, and become oriented tangentially (i.e., with their long axes perpendicular to the longitudinal axes of the neural tube); (c) early migration, during which the crest population expands uniformly to meet the dorsal apex of the somites; and (d) advanced migration, during which crest cells appear in the extracellular space dorsal to the somites. At the most advanced phases, the crest population at the dorsal midline decreased in number, with a concomitant loss of tangential orientation and the appearance of spaces between the cells. Extracellular components of the acellular spaces through which crest cells migrate are also described. The observations are discussed in terms of (1) those morphological changes undergone by crest cells during migration, and (2) possible factors that might delimit crest pathways. It is suggested that the operation of contact inhibition of movement within the crest population is sufficient to determine the direction of crest migration.     

Gap Junction–mediated Cell–Cell Communication Modulates Mouse Neural Crest Migration

Previous studies showed that conotruncal heart malformations can arise with the increase or decrease in α₁ connexin function in neural crest cells. To elucidate the possible basis for the quantitative requirement for α₁ connexin gap junctions in cardiac development, a neural crest outgrowth culture system was used to examine migration of neural crest cells derived from CMV43 transgenic embryos overexpressing α₁ connexins, and from α₁ connexin knockout (KO) mice and FC transgenic mice expressing a dominant-negative α₁ connexin fusion protein. These studies showed that the migration rate of cardiac neural crest was increased in the CMV43 embryos, but decreased in the FC transgenic and α₁ connexin KO embryos. Migration changes occurred in step with connexin gene or transgene dosage in the homozygous vs. hemizygous α₁ connexin KO and CMV43 embryos, respectively. Dye coupling analysis in neural crest cells in the outgrowth cultures and also in the living embryos showed an elevation of gap junction communication in the CMV43 transgenic mice, while a reduction was observed in the FC transgenic and α₁ connexin KO mice. Further analysis using oleamide to downregulate gap junction communication in nontransgenic outgrowth cultures showed that this independent method of reducing gap junction communication in cardiac crest cells also resulted in a reduction in the rate of crest migration. To determine the possible relevance of these findings to neural crest migration in vivo, a lacZ transgene was used to visualize the distribution of cardiac neural crest cells in the outflow tract. These studies showed more lacZ-positive cells in the outflow septum in the CMV43 transgenic mice, while a reduction was observed in the α₁ connexin KO mice. Surprisingly, this was accompanied by cell proliferation changes, not in the cardiac neural crest cells, but in the myocardium— an elevation in the CMV43 mice vs. a reduction in the α₁ connexin KO mice. The latter observation suggests that cardiac neural crest cells may have a role in modulating growth and development of non–neural crest– derived tissues. Overall, these findings suggest that gap junction communication mediated by α₁ connexins plays an important role in cardiac neural crest migration. Furthermore, they indicate that cardiac neural crest perturbation is the likely underlying cause for heart defects in mice with the gain or loss of α₁ connexin function.     

The role of phenylalanine in differentiating amphibian melanocytes

To see whether phenylalanine serves as a substrate in melanogenesis, hanging drop explants of neural crest from amphibian (Ambystoma maculatum and A. mexicanum) embryos were subjected on the seventh day in vitro to treatment with phenylalanine-³H and studied by means of light microscopic radioautography. All melanin-containing cells showed label. On the other hand, when puromycin, an inhibitor of protein synthesis, together with the labeled amino acid was administered to the cultures, no radioactivity was incorporated by pigmented cells. Comparable results were obtained when leucine was substituted for phenylalanine. In control experiments, puromycin and labeled tyrosine or 3,4-dihydroxyphenylalanine (DOPA), both known precursors for melanin synthesis, were administered to the neural crest cultures. In these experiments, puromycin had no effect on the incorporation of label by pigmented cells. Our data strongly indicate that in differentiating amphibian melanocytes with functional pigment-forming systems, phenylalanine is used in protein synthesis, but does not serve as a substrate for the tyrosine-tyrosinase system.In another series of experiments, explants of neuroepithelium (neural crest anlage) were grown from the time of explantation to the seventh day in vitro in the presence of phenyllactic acid, an analog of phenylalanine. Pigment cells developed normally.These results suggest that phenylalanine plays little or no role in pigment cell differentiation.     

Environmental influences on neural crest cell migration

Neural crest cells migrate extensively and interact with numerous tissues and extracellular matrix components during their movement. Cell marking techniques have shown that neural crest cells in the trunk of the avian embryo migrate through the anterior, but not posterior, half of each sclerotome and avoid the region around the notochord. A possible mechanism to account for this migratory pattern is that neural crest cells may be inhibited from entering the posterior sclerotome and the perinotochordal space. Thus, interactions with other tissue may prescribe the pattern of neural crest cell migration in the trunk. In contrast, interactions between neural crest cells and the extracellular matrix may mediate the primary interactions controlling neural crest cells migration in the head region. © 1993 John Wiley & Sons, Inc.     

Analysis of the origins and early fates of neural crest cells in caudal regions of avian embryos

Holmdahl divided vertebrate embryogenesis into two phases called primary and secondary body development. Three primary germ layers are delineated during primary body development and undergo morphogenesis to form primary organ rudiments. In contrast, during secondary body development, the tail bud (a mesenchymal mass of cells located at the caudal end of the embryo and derived principally from Hensen's node) directly forms secondary organ rudiments. We have been testing Holmdahl's concept of primary and secondary body development by mapping the embryonic structures that originate from the tail bud. In the present study, we examined the origins of neural crest cells in caudal regions of avian embryos and observed two populations: primary neural crest cells derived from ectoderm and secondary neural crest cells derived from tail bud. Both types of neural crest cells originate locally, and little or no displacement of these cells occurs along the longitudinal axis. Some secondary neural crest cells seem to colonize the surface epithelium, forming a mosaic derived from both ectoderm and tail bud. Other secondary neural crest cells form spinal ganglia, differentiating as sensory neurons, satellite cells, and Schwann cells. Despite their strikingly different origins and locations, primary and secondary neural crest cells give rise to similar structures.