Growth of Neural Crest Cells In Vitro Is Enhanced By Extracts From Silky Fowl Embryonic Tissues

In the Silky Fowl (SF) breed of chicken, most of the internal organs are infiltrated with melanocytes. Previous studies have shown that this generalized mesodermal pigmentation is not due to a cell autonomous abnormality of the melanocytes but to environmental factors able to promote both the homing of pigment cell precursors in abnormal embryonic sites and their proliferation and differentiation. To analyse the mode of these environmental cues, we tested the effect of SF embryo extract (SFEE) on cultured quail neural crest cells as compared with that of EE from normal chickens of the JA57 strain (JA57EE). We found that SFEE enhances crest cell proliferation as judged by ³H-TdR incorporation and cell counting. In contrast, no effect of SFEE was observed either on the proportion of cultured cells that are engaged into the melanocytic differentiation pathway or on the amount of melanin produced by each differentiated pigment cell. The simple observation, however, reveals that SFEE has a significant effect on pigmentation of the cultured quail neural crest cells. This effect has therefore to be accounted for by the general increase in cell number induced by SFEE. The question is raised as to whether the in vivo SF phenotype is generated exclusively by this mechanism.     

Differentiation of avian neural crest cells in vitro: Absence of a developmental bias toward melanogenesis

Summary Neural crest cells from quail embryos grown in standard culture dishes differentiate almost entirely into melanocytes within 4 or 5 days when chick embryo extract (CEE) or occasional lots of fetal calf serum (FCS) are included in the medium. Gel fractionation showed that the pigment inducing factor(s) present in these media is of high molecular weight (> 400 K daltons). In the absence of CEE, the neural tube can also stimulate melanocyte differentiation. Culture medium supplemented by selected lots of FCS permits crest cell proliferation but little overt differentiation after up to 2 weeks in culture if the neural tube is removed within 18 h of explantation in vitro. Subsequent addition of CEE to such cultures promotes complete melanocyte differentiation. Crest cells from White leghorn chick embryos also differentiate into melanocytes in the presence of CEE, but do not survive well in its absence. Melanocyte differentiation of crest cells from both quail and chick embryos can by suppressed by culturing under a dialysis membrane, even in the presence of the neural tube and CEE, but neuronal differentiation appears greatly enhanced.     

Wnt and BMP signaling govern lineage segregation of melanocytes in the avian embryo

Recent studies show that specification of some neural crest lineages occurs prior to or at the time of migration from the neural tube. We investigated what signaling events establish the melanocyte lineage, which has been shown to migrate from the trunk neural tube after the neuronal and glial lineages. Using in situ hybridization, we find that, although Wnts are expressed in the dorsal neural tube throughout the time when neural crest cells are migrating, the Wnt inhibitor cfrzb-1 is expressed in the neuronal and glial precursors and not in melanoblasts. This expression pattern suggests that Wnt signaling may be involved in specifying the melanocyte lineage. We further report that Wnt-3a-conditioned medium dramatically increases the number of pigment cells in quail neural crest cultures while decreasing the number of neurons and glial cells, without affecting proliferation. Conversely, BMP-4 is expressed in the dorsal neural tube throughout the time when neural crest cells are migrating, but is decreased coincident with the timing of melanoblast migration. This expression pattern suggests that BMP signaling may be involved in neural and glial cell differentiation or repression of melanogenesis. Purified BMP-4 reduces the number of pigment cells in culture while increasing the number of neurons and glial cells, also without affecting proliferation. Our data suggest that Wnt signaling specifies melanocytes at the expense of the neuronal and glial lineages, and further, that Wnt and BMP signaling have antagonistic functions in the specification of the trunk neural crest.     

Pigment cell pattern formation in Taricha torosa: The role of the extracellular matrix in controlling pigment cell migration and differentiation

The neural crest is a population of highly migratory mesenchymal cells that ultimately localize in specific sites and differentiate into a variety of cell types. This report describes studies on the factors governing the migratory pathways, differentiation, and ultimate localization of the neural crest-derived pigment cells (black melanophores and yellow xanthophores) in the California newt, Taricha torosa. Melanophores first appear scattered in the dorsal portion of the lateral neural crest migratory pathway (between the somites and the ectoderm). These cells are eventually found in two stripes: a dorsal stripe that runs along the apex of the somites, and a midbody stripe near the somite-lateral plate mesoderm border. Melanophores are not seen in the dorsal fin of prehatching embryos. Xanthophores can be identified with the light microscope using NH₄OH-induced autofluorescence of pteridines and in the transmission electron microscope (TEM) by the presence of pterinosomes. Xanthophores first appear scattered among the melanophores over the surface of the somites; these cells eventually are found between the two melanophore stripes and in the dorsal fin. We were interested in determining the roles of the extracellular matrix (ECM) in controlling the formation of pigment cell patterns in T. torosa. Immunocytochemistry, Alcian blue staining of paraffin sections and ruthenium red staining of thin sections (accompanied by Streptomyces hyaluronidase and chondroitinase ABC digestion) were used to identify the composition and distribution of the ECM surrounding the pigment cells at various stages during development. The adhesive glycoprotein fibronectin is found in the dorsal portion of the lateral neural crest migratory pathway as well as in the dorsal fin matrix. Glycosaminoglycans (GAG) are found primarily in the dorsal fin and in the ECM surrounding the notochord. The dorsal fin ECM contains hyaluronate (HA), which was identified in the TEM as Streptomyces hyaluronidase-sensitive 3–5 nm microfibrils, as well as sulfated proteoglycan aggregates. We then confronted T. torosa neural crest cells in vitro with known ECM molecules. When neural folds are explanted onto tissue culture plastic in half-strength L-15 medium containing 10% fetal calf serum (FCS), cells migrate from the explant and differentiate into melanophores after 6 to 9 days. Xanthophores appear in the cultures 2 to 4 days after the appearance of melanophores. When cultured on three-dimensional collagen gels, xanthophores migrate significantly farther (P < 0.01) onto and into the collagen than melanophores (336 ± 183 vs 196 ± 160 μm from the edge of the explant). When 2.5 mg/ml chondroitin sulfate (CS) is present in the collagen gel, the distance that both pigment cell types migrate from the explant is reduced, with the result being that only xanthophores invade the GAG-rich matrix. When 1 mg/ml HA is present in the collagen gel, the differentiation of pigment cells is inhibited. Melanophores appear 48 hr later than in control gels without HA, and the number of melanophores in the explant after 10 days is significantly reduced (P < 0.01; 26.6 vs 1.1 melanophores/explant). When 1 mg/ml of HA is added to the FCS-enriched medium over neural crest cells spreading on tissue culture plastic, there is a similar delay and inhibition of pigment cell differentiation. With 2 mg/ml of CS there is no effect on pigment cell differentiation in vitro. Melanophores eventually appear in the dorsal fin of T. torosa several weeks after hatching. When fragments of dorsal fin that contain no apparent melanophores are transferred onto tissue culture plastic, melanophores appear in the explants after a few days in culture. These results suggest the following model of ECM-cell interactions during pigment cell pattern formation in T. torosa: Pigment cells differentiate in regions of the embryo that contain relatively little GAG. Xanthophores are able to invade the GAG-rich dorsal fin, but melanophores can not. The melanophores that eventually appear in the dorsal fin are derived from the neural crest cells that invaded the fin during early development, and were delayed in differentiating by the presence of HA.     

Transforming growth factor-beta alters differentiation in cultures of avian neural crest-derived cells: effects on cell morphology, proliferation, fibronectin expression, and melanogenesis.

Neural crest cell differentiation is responsive to a variety of extrinsic signals that include extracellular matrix (ECM) molecules and growth factors. Transforming growth factor-beta (TGF-beta) has diverse, cell type-specific effects, many of which involve regulation of synthesis of ECM molecules and their cell surface receptors. We are studying both separate and potentially interrelated influences of ECM and growth factors on crest differentiation and report here that TGF-beta alters several aspects of crest cell behavior in vitro. Clusters of quail neural crest cells were cultured in the presence and absence of 400 pM TGF-beta 1 and examined at 1, 3, and 5 days. When examined at 5 days, there was a dramatic decrease in the number of melanocytes in treated cultures, regardless of the onset or duration of TGF-beta treatment. With continuous TGF-beta treatment, or with treatment only during crest cluster formation on explanted neural tubes, many cells increased in area, becoming extremely flat. These changes were evident beginning on Day 3. While quantitative analyses of video images documented the size increase, several aspects of motility were relatively unchanged. Synthesis of fibronectin (FN) by approximately 11% of cells on Day 3 and 31% of cells on Day 5 was demonstrated by immunocytochemistry and was associated with a sixfold increase in FN mRNA by Day 5. Experiments which correlated FN immunoreactivity with incorporation of bromodeoxyuridine suggested that the population of large, flat, FN-positive cells did not proliferate selectively and that there was a slower rate of proliferation in TGF-beta-treated cultures than in untreated cultures. The large FN-immunoreactive cells resemble cells derived from cephalic neural crest and raise interesting questions concerning potential roles for TGF-beta in regulating crest differentiation in vivo.     

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.     

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.     

A clonal approach to the problem of neural crest determination.

A fundamental question regarding neural crest development is the possible pluripotential nature of this embryonic tissue. As a first step in examining this problem, clonal techniques are used to produce homogeneous populations of crest cells. Primary cultures of these cells are obtained by explanting neural tubes from Japanese quail in vitro and allowing crest cells to migrate away. The explant is removed, the outgrowth is isolated, dissociated with trypsin, and the cells plated at clonal density. Colonies derived in this manner fall into the following categories: all cells of the colony pigmented; none of the cells pigmented; and some of the cells pigmented, the remainder unpigmented. Pigmented colonies generally arise from small, round cells whereas the non-pigmented colonies usually originate from large, flattened polymorphous cells. Differentiation of melanocytes does not preclude their continued proliferation. The pigment phenotype, in addition, is stable through at least 25 generations. That the mixed colonies, in fact, are clonally derived is shown by physically isolating single cells. The identity of the non-pigment cells was not established in the present work. A possible neural fate is suggested, however, since nerve-like cells develop after the petri plates become overgrown. Neural clones did not form even though nerve growth factor activity is present as a normal constituent of the culture medium and was added as a supplement in some instances. These techniques permit the preparation of large, homogeneous populations of neural crest cells and afford an opportunity to examine aspects of crest determination heretofore impossible to study.     

Phenotypic dissections of the Blastocladiella emersonii zoospore's developmental choice

A developmentally homogeneous neural crest cell population has been used to assay the role of environmental factors in regulating crest cell differentiation. If cultured on tissue culture plastic, virtually all of the cells of this population differentiate into melanocytes. In contrast, when these cells are cultured for 3 or more days on substrata “conditioned” by somite fibroblasts, the proportion of cells undergoing melanogenesis decreased and the proportion expressing formaldehyde-induced fluorescence (FIF), characteristic of catecholamine-containing cells, increased. For a limited period of culture on somite-conditioned substrata, some cells in the population exhibit both pigment granules and fluorescence. Collagen-coated substrata decreased the number of cells that formed pigment but did not stimulate FIF. In contrast, optimum doses of exogenous cellular fibronectin mimicked the effect of somite-conditioned substrata, suppressing melanogenesis and promoting FIF. Glycosaminoglycan-derivatized substrata (i.e., hyaluronic acid, various chondroitin sulfate preparations, and heparin) did not alter the differentiative homogeneity of the cultured crest cell populations. The choice and expression of phenotype by some members of a cultured crest cell population can, therefore, be affected by environmental stimuli provided in the form of certain substrate-attached macromolecules. We suggest that optimal concentrations of some extracellular matrix components produced by embryonic tissue and normally encountered by migrating crest cells may elicit the expression of FIF in crest cells that would otherwise follow a different developmental pathway.     

In vitro proliferation and terminal differentiation of quail neural crest cells in a defined culture medium

We report the formulation of a culture medium, medium MCDB202-21, that supports the in vitro proliferation of quail neural crest cells and their differentiation into melanocytes and adrenergic neuroblasts in the complete absence of serum and chick embryo extract. McKeehan & Ham's medium MCDB 202 was supplemented with hormones, stimulators of metabolism, vitamins, trophic factors, transport molecules, and small molecular nutrients.     

An Analysis of the Effects of Retinoic Acid and Other Retinoids on the Development of Adrenergic Cells from the Avian Neural Crest

In the present work, we have investigated the role of all-trans-retinoic acid (all-transRA), and several other natural and synthetic retinoids, in the development of adrenergic cells in quail neural crest cultures. Dose response studies using all-transRA and 13-cisRA revealed a dose-dependent increase in the number of adrenergic cells in neural crest cultures. Similar dose response studies using RA isomers and other natural retinoids did not result in the same increases. In order to determine the receptor mediating the effects of all-transRA in the neural crest, we tested several synthetic analogs which specifically bind to a particular RA receptor (RAR) subtype. We found that the compound AM 580, which activates the RAR-α, produced an increase in adrenergic cells similar to that seen with all-transRA. The compound TTNPB, which activates all RAR subtypes, also resulted in an increase in adrenergic cells. We conclude that the increase in adrenergic cells seen with all-transRA is mediated by RAR-α and possibly RAR-β. To further define the actions of all-transRA on the neural crest we incubated cultures with 5-bromo-2′-deoxyuridine (BrdU) to determine whether all-transRA could affect the rate of proliferation. The results show that while all-transRA did not increase the fraction of cells incorporating BrdU into their nuclei at early time points (24 h), it did increase BrdU incorporation by tyrosine hydroxylase (TH) positive cells at 5 days in culture. These findings demonstrate that the increase in adrenergic cells seen with all-transRA in neural crest cultures is likely due to an increase in the proliferation of cells already expressing TH.     

Early embryonic interaction of retinal pigment epithelium and mesenchymal tissue induces conversion of pigment epithelium to neural retinal fate in the silver mutation of the Japanese quail

The neural retina and retinal pigment epithelium (RPE) diverge from the optic vesicle during early embryonic development. They originate from different portions of the optic vesicle, the more distal part developing as the neural retina and the proximal part as RPE. As the distal part appears to make contact with the epidermis and the proximal part faces mesenchymal tissues, these two portions would encounter different environmental signals. In the present study, an attempt has been made to investigate the significance of interactions between the RPE and mesenchymal tissues that derive from neural crest cells, using a unique quail mutant silver (B/B) as the experimental model. The silver mutation is considered to affect neural crest-derived tissues, including the epidermal melanocytes. The homozygotes of the silver mutation have abnormal eyes, with double neural retinal layers, as a result of aberrant differentation of RPE to form a new neural retina. Retinal pigment epithelium was removed from early embryonic eyes (before the process began) and cultured to see whether it expressed any phenotype characteristic of neural retinal cells. When RPE of the B/B mutant was cultured with surrounding mesenchymal tissue, neural retinal cells were differentiated that expressed markers of amacrine, cone or rod cells. When isolated RPE of the B/B mutant was cultured alone, it acquired pigmentation and did not show any property characteristic of neural retinal cells. The RPE of wild type quail always differentiated to pigment epithelial cells. In the presence of either acidic fibroblast growth factor (aFGF) or basic FGF (bFGF), the RPE of the B/B mutant differentiated to neural retinal cells in the absence of mesenchymal tissue, but the RPE of wild type embryos only did so in the presence of 10–40 times as much aFGF or bFGF. These observations indicate that genes responsible for the B/B mutation are expressed in the RPE as well as in those cells that have a role in the differentiation of neural crest cells. They further suggest that development of the neural retina and RPE is regulated by some soluble factor(s) that is derived from or localized in the surrounding embryonic mesenchyme and other ocular tissues, and that FGF may be among possible candidates.     

Correlations between hyaluronan and epidermal proliferation as studied by [H]glucosamine and [H]thymidine incorporations and staining of hyaluronan on mitotic keratinocytes

The rates of keratinocyte proliferation and synthesis of Hyaluronan (HA) were studied in human whole-skin organ culture by labeling with [6-³H]glucosamine and [³H]thymidine, respectively, to reveal possible correlations between the two functions of the cell. HA distribution in epidermis was examined by staining with a specific probe prepared front cartilage proteoglycan. The keratinocyte proliferation rate was low on the first 2 culture days, but showed a tenfold increase on the third and fourth days while the synthesis of HA proceeded at a relatively stable level throughout the same period. The most intensive staining of HA occurred in the uppermost spinous cell layer, whereas mitotic cells resided in the basal and suprabasal layers. The keratinocytes under various stages of mitosis were surrounded by a HA staining not more intense than that around nondividing basal cells, but a thick pad of HA appeared rapidly between the daughter cells. These findings suggest that newly synthesized HA is associated with the separation of keratinocytes following mitosis but the majority of the synthesis and content of HA in epidermis is involved in other keratinocyte activities such as maintenance of the extracellular space and cell-cell interactions during migration and differentiation.     

The effect of aging on the synthesis of hexosamine-containing substances from rat costal cartilage. A decrease in sulfation of chondroitin sulfate with aging.

The amount of glycosaminoglycan (GAG) in dry costal cartilage tissue of rats decreased with aging, while the GAG content in mg DNA (unit cartilage cell) remained the same with aging. These results can be explained by the finding that the total number of cartilage cells decreased with aging. Electrophoretic analysis showed that chondroitin 4-sulfate was the major GAG in rat costal cartilage of various ages. Rat costal cartilage of different ages was incubated with radioactive precursors, and newly synthesized GAG was prepared and the radioactivity analyzed to determine the biosynthetic activity. As to changes in the radioactivity uptake with aging per mg dry cartilage tissue, aging influenced [35S]sulfate incorporation into GAG more significantly than [3H]glucosamine incorporation into GAG. There was a significant decrease in the specific radioactivity of [35S]sulfate per mg DNA (unit cartilage cell), whereas the specific radioactivity of [3H]glucosamine per mg DNA did not change significantly with aging. Both the total sulfotransferase activity and the specific activity per mg DNA decreased significantly with aging. Analysis of disaccharide units formed after chondroitinase ABC digestion of labeled GAG isolated from young and old cartilage showed that the percentage of incorporation of [3H]glucosamine into deltaDi-OS increased significantly with aging. These results suggested that the appearance of nonsulfated positions in the structure of the chondroitin sulfate chain increased with aging. On the basis of gel chromatography on Bio-Gel A-1.5 m no significant difference in the approximate molecular size of chondroitin sulfate was observed between the young and old GAG samples. The present study indicated that the sulfation of chondroitin sulfate chains from rat costal cartilage decreased with the process of aging.     

Hyaluronate-cell interaction : Effects of exogenous hyaluronate on muscle fibroblast cell surface composition

Evidence that exogenous hyaluronate (HA) binds to the surface of muscle fibroblast cultures was obtained by incubating confluent fibroblasts with ¹⁴C-HA purified from fibroblast cell surfaces. Surface-bound ¹⁴C-HA was operationally defined as material resistant to six saline washes and solubilized by brief trypsinization. All of the surface-bound radioactivity remains as authentic HA. Exposure of fibroblasts to 100 μg/ml cold HA caused a nearly 3-fold ‘reduction’ in incorporation of isotopic precursors into glycosaminoglycan (GAG); but when intracellular ¹⁴C precursors to GAG were quantitated, the entire ‘reduction’ could be accounted for by decreased precursor uptake. Exposure to exogenous HA altered the distribution of newly synthesized GAG by stimulating an increase in total GAG secreted to the medium at the expense of that bound to the culture surface. Qualitatively, the cell surface ratio of ¹⁴C-HA: ¹⁴C-sulfated GAG (SGAG) of HA-treated cells is about 2.5 times greater than that of untreated cells and the medium ratio is correspondingly reversed. This is primarily the result of stimulated ¹⁴C-SGAG release to the culture medium. Addition of cold HA to prelabeled cultures also stimulates the selective turnover of SGAG from the culture surface. Thus, exposure to HA alters the fibroblast surface by accumulation of exogenous HA as well as by stimulation of SGAG turnover.     

The sympathoadrenal lineage in avian embryos. II. Effects of glucocorticoids on cultured neural crest cells

The neural crest-derived precursors of the sympathoadrenal lineage depend on environmental cues to differentiate as sympathetic neurons and pheochromocytes. We have used the monoclonal antibody A2B5 as a marker for neuronal differentiation and antisera against catecholamine synthesis enzymes to investigate the differentiation of catecholaminergic cells in cultures of quail neural crest cells. Cells corresponding phenotypically to sympathetic neurons and pheochromocytes can be identified in neural crest cell cultures after 5-6 days in vitro. Expression of the A2B5 antigen precedes expression of immunocytochemically detectable levels of tyrosine hydroxylase in cultured neural crest cells. Glucocorticoid treatment decreases the proportion of TH+ neural crest cells that express neuronal traits. We conclude that environmental cues normally encountered by sympathoadrenal precursors in vivo can influence the differentiation of a subpopulation of cultured neural crest cells in the sympathoadrenal lineage.     

Cell cycle changes during neural crest cell differentiation in vitro.

Chick trunk neural tubes containing neural crest cells were cultured in vitro. Cell outgrowth from these neural tube explants consists primarily of a small stellate cell population. After 3 days in culture the small stellate cell population undergoes a remarkable change in morphology that is characterized by a more refractile appearance in the phase contrast microscope. Subsequent to this change in morphology, pigment granules become visible in the cytoplasm after 4 days in culture. After 6 days in culture, virtually all of the small stellate cells are pigmented. The cell cycle parameters of the small stellate cell population are: S = 4.4 ± 1.2 hr (SD). G2 = 1.5 ± 1.0 hr (SD). M = 1.7 ± 0.6 hr (SD). and Gl = 3.8 ± 1.0 hr (SD). Continuous label experiments demonstrate that (G1+G2+M) increases from 7 hr in Day 4 cells, as yet unpigmented, to 12 hr in Day 5 cells that have become pigmented. This change is consistent with an increase in G1 and/or G2 that is closely correlated with the appearance of pigment granules. It is of interest that this cell cycle change is correlated with a rather late event in the developmental program of these neural crest cells rather than with the earlier morphological change observed after 3 days in culture.     

From the Crest to the Periphery: Control of Pigment Cell Migration and Lineage Segregation

Pigment cells are one of many cell types derived from the neural crest. This review focuses on the mechanisms that control the timing and pathways of migration of pigment cells into the epidermis and determinants that control the differentiation of pigment cells. Several factors may control the timing and pattern of pigment cell migration in the dorsolateral space including the loss of inhibitory molecules in the pathway, the appearance of chemotactic molecules emanating from the dispersing dermatome, and the differentiation of pigment cells, which may be the only neural crest derivative capable of utilizing the substratum found in the dorsolateral path Control of pigment cell differentiation remains controversial. A working model presented in this review suggests that multipotent neural crest cells that disperse ventrally upon separation from the neural tube preserve neurogenic ability and lose melanogenic ability, whereas those cells that are arrested at the entrance to the dorsolateral path lose neurogenic ability so that the population becomes primarily melanogenic. During the time that the latter population is arrested in migration it is speculated that the neural crest cells are exposed to an environment comprised of specific extracellular matrix molecules and/or growth factors that enhance pigment cell differentiation.