Fibronectin combined with stem cell factor plays an important role in melanocyte proliferation,differentiation and migration in cultured mouse neural crest cells

Stem cell factor (SCF) is essential to the migration and differentiation of melanocytes during embryogenesis because mutations in either the SCF gene, or its ligand, KIT, result in defects in coat pigmentation in mice. Using a neural crest cell (NCC) primary culture system from wild-type mice, we previously demonstrated that KIT-positive and/or L-3, 4-dihydroxyphenylalanine (DOPA)-positive melanocyte precursors proliferate following the addition of SCF to the culture medium. Extracellular matrix (ECM) proteins are considered to play a role in the migration and differentiation of various cells including melanocytes. We cultured mouse NCCs in the presence of SCF in individual wells coated with ECM; fibronectin (FN), collagen I (CLI), chondroitin sulphate, or dermatan sulphate. More KIT-positive cells and DOPA-positive cells were detected in the presence of SCF on ECM-coated wells than on non-coated wells. A statistically significant increase in DOPA-positive cells was evident in FN and CLI wells. In contrast, in the absence of SCF, few DOPA-positive cells and KIT-positive cells were detected on either the ECM-coated or non-coated wells. We concluded that ECM affect melanocyte proliferation and development in the presence of SCF. To determine the key site of FN function, RGDS peptides in the FN sequence, which supports spreading of NCCs, were added to the NCC culture. The number of DOPA-positive cells decreased with RGDS concentration in a dose-dependent fashion. Immunohistochemical staining revealed the presence of integrin alpha5, a receptor of RGDS, in NCCs. These results suggest the RGDS domain of FN plays a contributory role as an active site in the induction of FN function in NCCs. In addition, we examined the effect of FN with SCF on the NCC migration by measuring cluster size, and found an increase in size following treatment with FN.     

Establishment and characterization of a mouse neural crest derived cell line (NCCmelan5)

Stem cell factor (SCF) and endothelin 3 (EDN3) are both necessary for melanocyte development. We have established an immortal cell population of neural crest cells from C57BL/6 mice, cultivating them with SCF, EDN3 and 15% fetal calf serum without feeder cells, and have designated that line as C57NCC SE. C57NCC SE consists of a population of melanocytes in various stages of differentiation. We used a single-cell cloning method, in which only one cell is transferred to each new culture plate, and succeeded in establishing an immortal cell line named NCCmelan5. All NCCmelan5 cells were positive for KIT (SCF receptor), HMB45 (human melanosomal antigen), tyrosinase-related protein-1 (TYRP1), tyrosinase-related protein-2 (TYRP2), tyrosinase and endothelin receptor B (EDNRB) and all could oxidize 3,4-dihydroxyphenylalanine (DOPA) to form melanin. Measurement of their DNA content revealed that 88.6% of the cells were in the G0-G1 phase, suggesting that they retained normal DNA ploidy. Thus, NCCmelan5 cells have the characteristics of mature melanocytes except that they are immortal; these cells may prove useful to study factors that directly affect melanogenesis and melanocyte development without the influence of feeder cells. It is clear that our attempt to establish immortal cell lines from murine neural crest cells would have never been successful without the addition of SCF and EDN3, since C57NCC SE and NCCmelan5 cells require those factors to proliferate.     

Effects of Ultraviolet Light on Melanocyte Differentiation: Studies with Mouse Neural Crest Cells and Neural Crest‐derived Cell Lines

To evaluate the etiologic role of ultraviolet (UV) radiation in acquired dermal melanocytosis (ADM), we investigated the effects of UVA and UVB irradiation on the development and differentiation of melanocytes in primary cultures of mouse neural crest cells (NCC) by counting the numbers of cells positive for KIT (the receptor for stem cell factor) and for the L ‐3,4‐dihydroxyphenylalanine (DOPA) oxidase reaction. No significant differences were found in the number of KIT‐ or DOPA‐positive cells between the UV‐irradiated cultures and the non‐irradiated cultures. We then examined the effects of UV light on KIT‐positive cell lines derived from mouse NCC cultures. Irradiation with UVA but not with UVB inhibited the tyrosinase activity in a tyrosinase‐positive cell line (NCCmelan5). Tyrosinase activity in the cells was markedly enhanced by treatment with α‐melanocyte‐stimulating hormone (α‐MSH), but that stimulation was inhibited by UVA or by UVB irradiation. Irradiation with UVA or UVB did not induce tyrosinase activity in a tyrosinase‐negative cell line (NCCmelb4). Levels of KIT expression in NCCmelan5 cells and in NCCmelb4 cells were significantly decreased after UV irradiation. Phosphorylation levels of extracellular signal‐regulated kinase 1/2 in cells stimulated with stem cell factor were also diminished after UV irradiation. These results suggest that UV irradiation does not stimulate but rather suppresses mouse NCC. Thus if UV irradiation is a causative factor for ADM lesions, it would not act directly on dermal melanocytes but may act in indirect manners, for instance, via the overproduction of melanogenic cytokines such as α‐MSH and/or endothelin‐1.     

Stem Cell Factor Regulates Human Melanocyte-Matrix Interactions

Stem cell factor (SCF) is hypothesized to play a critical role in the migration of melanocytes during embryogenesis because mutations in either the SCF gene, or its ligand, c-kit, result in defects in coat pigmentation in mice and in skin pigmentation in humans. In this report we directly show that SCF alters the adhesion and migration of human melanocytes to extracellular matrix (ECM) ligands and regulates integrin expression at the protein level. SCF decreased adhesion of neonatal and fetal cells to collagen IV, and increased attachment of fetal cells to laminin. Attachment of fetal cells to fibronectin was decreased, but was unchanged in neonatal cells. Flow cytometry analysis of neonatal melanocytes showed that SCF down-regulated the expression of the α2 receptor, and up-regulated the expression of the α3, α5 and β1 integrin receptors. SCF down-regulated expression of α2, α5 and β1 integrins by fetal melanocytes, and up-regulated expression of the αv and α3 integrin receptors. Analysis of melanocyte migration using time-lapse videomicroscopy showed that SCF significantly increased migration of neonatal, but not fetal, melanocytes on fibronectin (FN). We conclude that SCF regulates integrin expression at the protein level and that SCF has pleiotropic effects on melanocyte attachment and migration on ECM ligands. We suggest that this may be one mechanism by which SCF regulates melanocyte migration during development of the skin.     

Insights into stem cell factor chemotactic guidance of neural crest cells revealed by a real-time directionality-based assay

The extracellular environment through which neural crest cells (NCCs) translocate and differentiate plays a crucial role in the determination of cell migration and homing. In the trunk, NCC-derived melanocyte precursor cells (MPCs) take the dorsolateral pathway and colonize the skin, where they differentiate into pigment cells (PCs). Our hypothesis was that the skin, the MPCs' target tissue, may induce a directional response of NCCs toward diffusible factor(s). We show that the treatment of in vitro NCCs with skin extract (SE) or Stem Cell Factor (SCF) contributes to maintaining proliferative activity, accelerates melanocyte differentiation, and guides a subpopulation of NCCs by chemotaxis toward the gradient source of these factors, suggesting that they may represent the MPCs' subpopulation. Current data on stimulated directional persistence of NCCs supports the participation of diffusible molecules in the target colonization mechanism, guiding MPCs to migrate and invade the skin. Our results show similar effects of SE and SCF on NCC growth, proliferation and pigment cell differentiation. Also, the use of a proven real-time directionality-based objective assay shows the directional migration of NCCs toward SE and SCF, indicating that the epidermal SCF molecule may be involved in the chemotactic guidance mechanism of in vivo NCCs. Although SCF is the strongest candidate to account for these phenomena, the nature of other factor(s) affecting NCC-oriented migration remains to be investigated. This data amplifies the functional scope of trophic factors by involving them in new cell behaviors such as molecular guidance in the colonization mechanism of embryonic cells.     

Establishment by an Original Single‐cell Cloning Method and Characterization of an Immortal Mouse Melanoblast Cell Line (NCCmelb4)

We devised a unique new single‐cell cloning method which uses microscope cover glasses and established a melanoblast cell line derived from mouse neural crest cells. A microscope cover glass was nicked and broken into small pieces and put on a dish. Culture medium and a suspension of 20–30 cells/ml were dropped in the dish. After 1–3 d, a piece of glass to which only one cell was adhered was picked up and transferred to another dish containing culture medium. The greatest advantage of this method is that the derivation of a colony from a single cell can be directly confirmed by microscopy and there is no risk of migratory cells being contaminated by other colonies. Using this single‐cell cloning method, in this study we established a cell line derived from a neural crest cell line (NCC‐S4.1) and designated it as NCCmelb4. When the culture medium was supplemented with stem cell factor (SCF) alone, NCCmelb4 cells were KIT‐positive and tyrosinase‐negative melanocyte precursors; they remained at an immature and undifferentiated stage. When the medium was supplemented with phorbol 12‐o‐tetradecanoyl‐13‐acetate (TPA) + cholera toxin (CT), the cell morphology changed and became l ‐3,4‐dihydroxyphenylalanine (DOPA)‐positive. This observation indicates that the NCCmelb4 cells are capable of further differentiation with suitable stimulation. NCCmelb4 cells derived from the mouse neural crest has characteristics of melanocyte precursors (melanoblasts), and is a cell line which can be utilized to study differentiation‐inducing factors and growth factors without the effects of feeder cells.     

Neural crest motility on fibronectin is regulated by integrin activation

Cell migration is essential for proper development of numerous structures derived from embryonic neural crest cells (NCCs). Although recent work has shown that receptor recycling plays an important role in NCC motility on laminin, the molecular mechanisms regulating NCC motility on fibronectin remain unclear. One mechanism by which cells regulate motility is by modulating the affinity of integrin receptors. Here, we provide evidence that cranial and trunk NCCs rely on functional regulation of integrins to migrate efficiently on fibronectin (FN) in vitro. For NCCs cultured on fibronectin, velocity decreases after Mn2+ application (a treatment that activates all surface integrins) while velocity on laminin (LM) is not affected. The distribution of activated integrin beta 1 receptors on the surface of NCCs is also substratum-dependent. Integrin activation affects cranial and trunk NCCs differently when cultured on different concentrations of FN substrata; only cranial NCCs slow in a FN concentration-dependent manner. Furthermore, Mn2+ treatment alters the distribution and number of activated integrin beta 1 receptors on the surface of cranial and trunk NCCs in different ways. We provide a hypothesis whereby a combination of activated surface integrin levels and the degree to which those receptors are clustered determines NCC motility on fibronectin.     

Ednrb2 orients cell migration towards the dorsolateral neural crest pathway and promotes melanocyte differentiation

Endothelin receptors B (Ednrb) are involved in the development of the enteric and melanocytic lineages, which originate from neural crest cells (NCCs). In mice, trunk NCCs and their derivatives express only one Ednrb. In quail, trunk NCCs express two Ednrb: Ednrb and Ednrb2. Quail Ednrb is expressed in NCCs migrating along the ventral pathway, which gives rise to the peripheral nervous system, including enteric ganglia. Ednrb2 is upregulated in NCCs before these cells enter the dorsolateral pathway. The NCCs migrating along the dorsolateral pathway are melanocyte precursors. We analyzed the in vitro differentiation and in ovo migration of mouse embryonic stem (ES) cells expressing and not expressing Ednrb2. We generated a series of transfected ES cell lines expressing Ednrb2. This receptor, like Ednrb, oriented genuine ES cells towards melanocyte lineage differentiation in vitro. The in ovo migration of Ednrb2-expressing ES cells was massively oriented towards the dorsolateral pathway, unlike that of WT or Ednrb-expressing ES cells. Thus, Ednrb2 is involved in melanoblast differentiation and migration.     

Effects of ultraviolet light on melanocyte differentiation: studies with mouse neural crest cells and neural crest-derived cell lines

To evaluate the etiologic role of ultraviolet (UV) radiation in acquired dermal melanocytosis (ADM), we investigated the effects of UVA and UVB irradiation on the development and differentiation of melanocytes in primary cultures of mouse neural crest cells (NCC) by counting the numbers of cells positive for KIT (the receptor for stem cell factor) and for the L-3,4-dihydroxyphenylalanine (DOPA) oxidase reaction. No significant differences were found in the number of KIT- or DOPA-positive cells between the UV-irradiated cultures and the non-irradiated cultures. We then examined the effects of UV light on KIT-positive cell lines derived from mouse NCC cultures. Irradiation with UVA but not with UVB inhibited the tyrosinase activity in a tyrosinase-positive cell line (NCCmelan5). Tyrosinase activity in the cells was markedly enhanced by treatment with alpha-melanocyte-stimulating hormone (alpha-MSH), but that stimulation was inhibited by UVA or by UVB irradiation. Irradiation with UVA or UVB did not induce tyrosinase activity in a tyrosinase-negative cell line (NCCmelb4). Levels of KIT expression in NCCmelan5 cells and in NCCmelb4 cells were significantly decreased after UV irradiation. Phosphorylation levels of extracellular signal-regulated kinase 1/2 in cells stimulated with stem cell factor were also diminished after UV irradiation. These results suggest that UV irradiation does not stimulate but rather suppresses mouse NCC. Thus if UV irradiation is a causative factor for ADM lesions, it would not act directly on dermal melanocytes but may act in indirect manners, for instance, via the overproduction of melanogenic cytokines such as alpha-MSH and/or endothelin-1.     

Extracellular matrix modulates the function of human melanocytes but not melanoma cells

Normal human epidermal melanocytes are attached to a basement membrane, a specialized form of extracellular matrix (ECM), located between the epithelium and underlying dermal tissues. To determine whether ECM influences pigmented cell behavior in vitro, human epidermal melanocytes and melanoma cells were cultured on uncoated or ECM-coated plastic culture surfaces, and a comparison was made between growth and function in the presence or absence of ECM. Melanocytes cultured on ECM-coated surfaces developed flatter and larger cell bodies and produced more melanin than melanocytes cultured on uncoated surfaces. In the presence of phorbol-myristate-acetate and cholera toxin, the rate of melanocyte replication was increased by ECM. In the absence of these mitogens, ECM significantly enhanced the adhesiveness of nonproliferating melanocytes. ECM had little or no effect on these parameters (morphology, tyrosinase activity, replication) in a pigmented human malignant melanoma cell line. These findings indicate that normal human epidermal pigment cells have the ability to recognize and respond to matrix signals, whereas this capacity appears to be absent in melanoma cells.     

Dual origin of melanocytes defined by Sox1 expression and their region‐specific distribution in mammalian skin

Melanocytes are pigment‐producing cells generated from neural crest cells (NCCs) that delaminate from the dorsal neural tube. The widely accepted premise that NCCs migrating along the dorsolateral pathway are the main source of melanocytes in the skin was recently challenged by the finding that Schwann cell precursors are the major cellular source of melanocytes in the skin. Still, in a wide variety of vertebrate embryos, melanocytes are exclusively derived from NCCs. In this study, we show that a NCC population that is not derived from Sox1⁺ dorsal neuroepithelial cells but are derived from Sox1^? cells differentiate into a significant population of melanocytes in the skin of mice. Later, these Sox1^? cells clearly segregate from cells that originated from Sox1⁺ dorsal neuroepithelial cell‐derived NCCs. The possible derivation of Sox1^? cells from epidermal cells also strengthens their non‐neuroepithelial origin.     

Cranial neural crest recycle surface integrins in a substratum-dependent manner to promote rapid motility

Cell migration is essential for proper development of numerous structures derived from embryonic neural crest cells (NCCs). Although the migratory pathways of NCCs have been determined, the molecular mechanisms regulating NCC motility remain unclear. NCC migration is integrin dependent, and recent work has shown that surface expression levels of particular integrin alpha subunits are important determinants of NCC motility in vitro. Here, we provide evidence that rapid cranial NCC motility on laminin requires integrin recycling. NCCs showed both ligand- and receptor-specific integrin regulation in vitro. On laminin, NCCs accumulated internalized laminin but not fibronectin receptors over 20 min, whereas on fibronectin neither type of receptor accumulated internally beyond 2 min. Internalized laminin receptors colocalized with receptor recycling vesicles and were subsequently recycled back to the cell surface. Blocking receptor recycling with bafilomycin A inhibited NCC motility on laminin, indicating that substratum-dependent integrin recycling is essential for rapid cranial neural crest migration.     

神经嵴细胞和神经嵴病及其致病机制的研究进展

神经嵴细胞(neural crest cells,NCCs)是一类脊椎动物特有的可迁移的多能干细胞,其可分化为软骨细胞、神经元和黑色素细胞等多种类型细胞。NCCs的形成、迁移和分化受到严格调控,任何扰乱NCCs发育的因素都可导致胚胎发育畸形。由神经嵴细胞发育异常所导致的一系列疾病统称为神经嵴病(neurocristopathies,NCPs)。NCPs种类繁多且表型复杂,可累及人体多个部位(颅面部、心脏、肠胃和皮肤等),严重危害患者的身体机能和心理健康。NCPs占所有出生缺陷患儿的1/3,遗传因素是导致NCPs的主要风险因素,但环境风险因子以及基因–环境交互作用异常也可导致NCPs。本文对神经嵴细胞和神经嵴病及其致病机制进行综述,为系统认知神经嵴细胞发育以及神经嵴病提供参考,为了解神经嵴病的病因以及开展有效防控提供科学支撑。     

Cranial neural crest cell migration in cockatiel Nymphicus hollandicus (Aves: Psittaciformes)

Parrots have developed unique jaw muscles in their evolutionary history. The M. pseudomasseter, which completely covers the lateral side of the jugal bar, is regarded as a jaw muscle unique to parrots. In a previous study, I presented a hypothesis on the relevance of modifications in the regulation of cranial neural crest cell (NCC) development to the generation of this novel jaw muscle based on histological analyses (Tokita [2004] J Morphol 259:69-81). In the present study, I investigated distribution and migration patterns of cranial neural crest cells (NCCs) through parrot embryogenesis with immunohistochemical techniques to further understand the role of cranial NCCs in the evolution of the M. pseudomasseter, and to provide new information on the relative plasticity in cranial NCC migration at early stages of avian development. The basic nature of cranial NCC development was mostly conserved between chick and parrot. In both, cranial NCCs migrated from the dorsal tip of the neural tube in a ventral direction. Three major populations were identified in their cranial NCCs. Migration pathways of these cells were almost identical between chick and parrot. The principal difference was seen in the relative timing of cranial NCC migration. In the parrot, cranial NCC migration into the first pharyngeal arch was more advanced than in the chick at early stages of development. Such a temporal shift in cranial NCC migration might influence architectural patterning of parrot jaw muscles that generates new muscle like M. pseudomasseter.     

Immune responses in a mouse model of vitiligo with spontaneous epidermal de‐ and repigmentation

To generate a mouse model of spontaneous epidermal depigmentation, parental h3TA2 mice, expressing both a human‐derived, tyrosinase‐reactive T‐cell receptor on T cells and the matching HLA‐A2 transgene, were crossed to keratin 14‐promoter driven, stem cell factor transgenic (K14‐SCF) mice with intra‐epidermal melanocytes. In resulting Vitesse mice, spontaneous skin depigmentation precedes symmetrical and sharply demarcated patches of graying hair. Whereas the SCF transgene alone dictates a greater retinoic acid receptor‐related orphan receptor gamma (RORγt)⁺ T‐cell compartment, these cells displayed markedly increased IL‐17 expression within Vitesse mice. Similar to patient skin, regulatory T cells were less abundant compared with K14‐SCF mice, with the exception of gradually appearing patches of repigmenting skin. The subtle repigmentation observed likely reflects resilient melanocytes that coexist with skin‐infiltrating, melanocyte‐reactive T cells. Similar repigmenting lesions were found in a different TCR transgenic model of vitiligo developed on an SCF transgenic background, supporting a role for SCF in repigmentation.     

Heterogeneity of neural crest-derived melanocytes

The majority of melanocytes originate from the neural crest cells (NCC) that migrate, spread on the whole embryo’s body to form elements of the nervous system and skeleton, endocrinal glands, muscles and melanocytes. Human melanocytes differentiate mainly from the cranial and trunk NCC. Although melanocyte development has traditionally been associated with the dorsally migrating trunk NCC, there is evidence that a part of melanocytes arise from cells migrating ventrally. The ventral NCC differentiate into neurons and glia of the ganglia or Schwann cells. It has been suggested that the precursors for Schwann cells differentiate into melanocytes. As melanoblasts travel through the dermis, they multiply, follow the process of differentiation and invade the forming human fetal epidermis up to third month. After birth, melanocytes lose the ability to proliferate, except the hair melanocytes that renew during the hair cycle. The localization of neural crest-derived melanocytes in non-cutaneous places e.g. eye (the choroid and stroma of the iris and the ciliary body), ear (cells of the vestibular organ, cochlear stria vascularis), meninges of the brain, heart seems to indicate that repertoire of melanocyte functions is much wider than we expected e.g. the protection of tissues from potentially harmful factors (e.g. free radicals, binding toxins), storage ions, and anti-inflammatory action.