Development of cells containing catecholamines and somatostatin-like immunoreactivity in neural crest cultures: relationship of DNA synthesis to phenotypic expression

The goal of our work is to understand the mechanisms which regulate the differentiation of embryonic neural crest cells into a number of adult cell types, including several classes of neurons. As one aspect of this analysis, the relationship between DNA synthesis and the ontogeny of cells with catecholamines and somatostatin-like immunoreactivity (SLI) in neural crest cell cultures has been investigated. Most of the precursors of the catecholamine- and SLI-positive cells carry out DNA synthesis. As these cells differentiate, their ability to carry out DNA synthesis declines. However, a small percentage of cells continue to synthesize DNA after they become catecholamine or SLI positive. There is no apparent difference between the temporal pattern of DNA synthesis in the precursors of catecholamine-positive cells with SLI and those without SLI. Thus, the time of withdrawal from the cell cycle does not distinguish the lineage of cells that are catecholamine and SLI positive from those that are catecholamine positive and SLI negative.     

Cellular fibronectin promotes adrenergic differentiation of quail neural crest cells in vitro

We have investigated the interaction of cellular fibronectin (CFN) with cultured quail neural crest cells and its possible role in crest cell migration and differentiation. In vitro, quail neural crest cells from the trunk region differentiate into at least two morphologically recognizable cell types, melanocytes and adrenergic nerve cells. The latter often aggregate spontaneously into ganglia-like structures. We found that neither melanocytes nor adrenergic nerve cells synthesize CFN. However, both cell types readily interacted with exogenous CFN: Melanocytes removed CFN from the substratum and accumulated it in an aggegated form on their upper cell surface, whereas unpigmented cells migrated on the CFN substratum, often rearranging it into a fibrillar network. The adsorption of CFN by melanocytes was apparently without further consequences. However, catecholamine-positive cells were substantially increased after treatment with exogeneous fibronectin. The stimulation of adrenergic differentiation of neural crest cells is the first evidence for a positive regulatory role of fibronectin in differentiation.     

Inhibition of the adrenergic phenotype in cultured neural crest cells by norepinephrine uptake inhibitors

Tricyclic antidepressants in combination with in vitro clonal analysis of quail neural crest cells were used to examine the role the norepinephrine uptake mechanism might play in the development of adrenergic neural crest derivatives. Norepinephrine (NE) uptake inhibitors blocked expression of the adrenergic phenotype by neural crest cells. The degree of inhibition of phenotypic expression correlated with the potency and specificity of the uptake inhibitors. The drugs acted during the early phase of in vitro development, i.e., several days before overt expression of the adrenergic phenotype in clonal culture. They were nontoxic, and a chronic exposure of the cells to NE uptake inhibitors was necessary to cause an effect. These observations suggest that norepinephrine and possibly related neurotransmitters play a direct or indirect role in the expression of the adrenergic phenotype by neural crest cells and that tricyclic antidepressants may affect neurogenesis during sensitive stages of embryonic development. The data may reflect in vivo mechanisms, since there are neurotransmitters present in the migratory pathway of presumptive sympathetic neurons and the norepinephrine uptake system is expressed in the embryo by these cells before they synthesize and accumulate catecholamines.     

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.     

Induction and differentiation of the neural crest

The neural crest is a population of cells that forms at the junction between the epidermis and neural plate in vertebrate embryos. Recent progress has elucidated the identity and timing of molecular events responsible for the earliest steps in neural crest development, particularly those involving the induction and its migration. Concomitantly, advances have been made in the identification, purification and generation of neural crest stem cells at various developmental stages that deepens our understanding of the plasticity and restriction of neural crest differentiation.     

Membrane properties of cultured rat sympathetic neurons: Morphological studies of adrenergic and cholinergic differentiation

Dissociated neurons from the newborn rat superior cervical ganglion were grown under conditions which lead to either adrenergic or cholinergic differentiation. Lectins and toxins were used to detect differences in the cell membrane associated with transmitter status, age of the neurons, or location on the neurons. These ligands were made visible in the light or electron microscope by coupling to rhodamine or colloidal gold. The density of binding sites for concanavalin A (Con A), ricin (RCA₆₀), and wheat germ agglutinin (WGA) increased with age in culture on both adrenergic and cholinergic cells. Soybean agglutinin (SBA) binding increased about threefold on adrenergic axons, but failed to increase on neurons induced to become cholinergic by medium conditioned by rat heart cells (CM). The effect of CM on SBA binding paralleled previously described effects of CM on transmitter production; the CM binding pattern developed slowly and was not readily reversible. Mature adrenergic neurons also appeared to bind more WGA than neurons in CM cultures. Tetanus toxin gold binding was uniform, but low, on axons of adrenergic and cholinergic neurons at all ages. In contrast, cholera toxin binding decreased with age on adrenergic axons. Binding sites for SBA and tetanus toxin were found to be less numerous on the cell body surface than on the axonal surface. Thus growth in CM induces fundamental changes in the phenotype of developing sympathetic neurons involving the cell membrane as well as transmitter choice. Differences also appear with maturation and between axonal and somatic cell surface membranes.     

Coexpression of sensory and autonomic neurotransmitter traits by avian neural crest cells in vitro

This study shows that explants of quail neural crest cultured in a medium containing serum and chick embryo extract give rise to large numbers of cells expressing immunoreactivity for substance P (SP), a neuropeptide found in sensory neurons. These cells arise from cycling precursors, but do not appear to divide after expressing SP. The SP-positive cells in cranial neural crest cultures express both neurofilament and the Q211 antigen, but those in trunk cultures express only the Q211 antigen. In both cranial and trunk cultures, large subpopulations of the SP-positive cells express tyrosine hydroxylase and/or choline acetyltransferase, neurotransmitter markers characteristic of autonomic neurons. This finding argues against the idea that SP expression necessarily indicates commitment to the sensory neuron lineage. I further show that embryonic dorsal root ganglion (DRG) cells retain the ability to coexpress SP and tyrosine hydroxylase in vitro although to a lesser extent than do neural crest cells.     

Head and trunk neural crest in vitro: Autonomic neuron differentiation

Isolated cultures of premigratory neural crest cells were used to study the initial stages of autonomic neuron development. Autonomic neurons are phenotypically characterized on the basis of their neurotransmitter synthetic enzymes, dopamine β-hydroxylase (DBH) and choline acetyltransferase (CAT). DBH converts dopamine to norepinephrine in noradrenergic neurons while CAT synthesizes acetylcholine from choline in cholinergic neurons. Activities of both enzymes were detected in isolated cultures of trunk neural crest and head neural crest. DBH was detected at all culture ages examined (from 1 to 20 days) whereas CAT activity was first detected only after 5 days in vitro. While specific enzyme activity of DBH peaks on Day 6 and specific enzyme activity of CAT peaks on Day 10, absolute activity for both enzymes increases throughout the 20-day culture period. DBH and CAT develop in vitro without any spinal presynaptic input, without typical target tissue interactions (such as blood vascular elements or heart tissue), and without addition of conditioned medium factors.     

Coexpression of sensory and autonomic neurotransmitter traits by avian neural crest cells in vitro.

This study shows that explants of quail neural crest cultured in a medium containing serum and chick embryo extract give rise to large numbers of cells expressing immunoreactivity for substance P (SP), a neuropeptide found in sensory neurons. These cells arise from cycling precursors, but do not appear to divide after expressing SP. The SP-positive cells in cranial neural crest cultures express both neurofilament and the Q211 antigen, but those in trunk cultures express only the Q211 antigen. In both cranial and trunk cultures, large subpopulations of the SP-positive cells express tyrosine hydroxylase and/or choline acetyltransferase, neurotransmitter markers characteristic of autonomic neurons. This finding argues against the idea that SP expression necessarily indicates commitment to the sensory neuron lineage. I further show that embryonic dorsal root ganglion (DRG) cells retain the ability to coexpress SP and tyrosine hydroxylase in vitro, although to a lesser extent than do neural crest cells.     

Neuronal differentiation of mouse neural crest cells in vitro

The purpose of the present study is to analyze the effect of serum or chick embryo extract (CEE) on the neuronal differentiation of the mouse neural crest cells. When the crest cells were cultured in the medium containing serum at low concentration (5% calf serum), neurite outgrowth was observed. The active outgrowth was detected at 3-4 days in culture. However, in the medium supplemented with 20% calf serum, no neurite appeared, and the crest cells remained fibroblast-like. The differentiation of adrenergic neurons was observed when the crest cells were cultured in the medium containing CEE along with serum.     

Regeneration, neural crest derivatives and retinoids: a new synthesis

Consideration of recent data from diverse fields of biology permits the presentation of a general theory to explain the underlying mechanism and phylogenetic distribution of vertebrate regenerative capacity. It is suggested that dermal xanthophores, which are neural crest derivatives that contain carotenoid pigments, serve as storage reservoirs for proretinoids. At trauma, carotenoids are released and are converted to retinoids. The spatial distribution of xanthophores at the amputation site determines the amount of carotenoids released, which in turn determines the number of cells which will participate in regeneration and their degree of dedifferentiation. It also influences the proliferative and morphogenetic potential of the blastema. The theory is based on several factors. (1) The pluripotency of neural crest derivatives in general and that of chromatophores in particular; (2) The storage metabolism of carotenoids, especially their convertability to retinoids; (3) The known roles of retinoids in regeneration; (4) Evidence suggesting a relationship between carotenoids and regeneration in invertebrates; and (5) Dynamic characteristics of regenerating systems. The theory is experimentally testable with currently available technology. Specific review of data concerning urodele lens regeneration illustrates the theory. Evidence from amphibian limb regeneration is also presented. Methods of evaluation of other regeneration systems are outlined.     

Common precursors for neural and mesectodermal derivatives in the cephalic neural crest.

The cephalic neural crest (NC) of vertebrate embryos yields a variety of cell types belonging to the neuronal, glial, melanocytic and mesectodermal lineages. Using clonal cultures of quail migrating cephalic NC cells, we demonstrated that neurons and glial cells of the peripheral nervous system can originate from the same progenitors as cartilage, one of the mesectodermal derivatives of the NC. Moreover, we obtained evidence that the migrating cephalic NC contains a few highly multipotent precursors that are common to neurons, glia, cartilage and pigment cells and which we interprete as representative of a stem cell population. In contrast, other NC cells, although provided with identical culture conditions, give rise to clones composed of only one or some of these cell types. These cells thus appear restricted in their developmental potentialities compared to multipotent cells. It is therefore proposed that, in vivo, the active proliferation of pluripotent NC cells during the migration process generates distinct subpopulations of cells that become progressively committed to different developmental fates.     

Wnt-frizzled signaling in the induction and differentiation of the neural crest

The neural crest is a transient population of multipotent progenitors arising at the lateral edge of the neural plate in vertebrate embryos. After delamination and migration from the neuroepithelium, these cells contribute to a diverse array of tissues including neurons, smooth muscle, craniofacial cartilage, bone cells, endocrine cells and pigment cells. Considerable progress in recent years has furthered our understanding at a molecular level of how this important group of cells is generated and how they are assigned to specific lineages. Here we review a number of recent studies supporting a role for Wnt signaling in neural crest induction, differentiation, and apoptosis. We also summarize the timing of expression of a number of Wnt ligands and receptors with respect to neural crest induction.     

Molecular probes for the development and plasticity of neural crest derivatives

We have isolated cDNA clones for several mRNAs expressed in sympathetic neurons but not in adrenal chromaffin cells, two neural crest derivatives thought to share a common precursor. The tissue specificity, developmental expression, and hormonal regulation of these genes have been characterized using Northern blot and in situ hybridization analysis. We find that these mRNAs are independently regulated in development rather than synchronously induced. Our evidence also implicates Nerve Growth Factor (NGF) in the induction of one of these genes in postmigratory crest cells. Two of these genes become induced in mature chromaffin cells, which express a neuronal morphology in response to NGF. These results support the idea that the phenotypic plasticity of neural crest derivatives reflects a common precursor, the multipotentiality of which is sustained through terminal differentiation.     

Prokineticin-1 modulates proliferation and differentiation of enteric neural crest cells

Prokineticins (Prok-1 and Prok-2) belong to a newly identified AVIT protein family. They are involved in variety of activities in various tissues, including smooth muscle contraction of the gastrointestinal tract and promoting proliferation of endothelial cells derived from adrenal gland. Importantly, they also act as the survival factors to modulate growth and survival of neurons and hematopoietic stem cells. In this study we demonstrated that Prok-1 (but not Prok-2) protein is expressed in the mucosa and mesenchyme of the mouse embryonic gut during enteric nervous system development. Its receptor, PK-R1 is expressed in the enteric neural crest cells (NCCs). To elucidate the physiological role(s) of Prok-1 in NCCs, we isolated the NCCs from the mouse embryonic gut (E11.5) and cultured them in the form of neurospheres. In an in vitro NCC culture, Prok-1 was able to activate both Akt and MAPK pathways and induce the proliferation and differentiation (but not migration) of NCCs via PK-R1. Knock-down of PK-R1 using siRNA resulted in a complete abolishment of Prok-1 induced proliferation. Taken together, it is the first report demonstrating that Prok-1 acts as a gut mucosa/mesenchyme-derived factor and maintains proliferation and differentiation of enteric NCCs.