Neural crest cell behavior in white and dark larvae of Ambystoma mexicanum: differences in cell morphology, arrangement, and extracellular matrix as related to migration

Melanocytes of white (d/d) larvae of the Mexican axolotl (Ambystoma mexicanum) are confined to the dorsal midline of the trunk region, whereas in dark (D/-) larvae they are spread laterally on the flank as well, where they contribute to the normal pigment pattern of the trunk. Pigment cell migration in the subepidermal space of white larvae is inhibited by the white epidermis (Dalton '50; Keller et al., '82). The present scanning electron microscopic study describes a well-defined sequence of changes in shape and arrangement of neural crest cells during and after their segregation from the neural tube in both dark and white axolotls. The morphology of the neural crest cells migrating in the subepidermal pathway of dark larvae is correlated with their motile behavior and pattern of migration in vivo, as described by time-lapse cinemicrography (Keller and Spieth, '83). Also, the structures of the matrix material in the subepidermal space of dark and white axolotls differ in ways that may be related to the epidermal inhibition of migration in the latter. Numerous possibilities for contact guidance offered by the structure and topography of the substrata, neighboring cells, and the extracellular matrix in the migration path are described and discussed.     

Timing in the regulation of neural crest cell migration: retarded "maturation" of regional extracellular matrix inhibits pigment cell migration in embryos of the white axolotl mutant

In larvae of the white axolotl mutant (Ambystoma mexicanum), contrary to normal dark ones, trunk pigmentation is restricted because the epidermis is unable to support subepidermal migration of pigment cells from the neural crest (NC). This study examines whether the subepidermal extracellular matrix (ECM) is the defective component which prevents pigment cell migration in the white embryo. We transplanted subepidermal ECM, adsorbed in vivo on membrane microcarriers, from and to white and dark embryos in various combinations. White embryos have demonstrated normal NC cell migration along the medioventral pathway, and in order to test the effects of medial ECM on subepidermal migration, this ECM was similarly transplanted. Carriers with ECM attached were inserted subepidermally in host embryos at a premigratory NC stage. Control carriers without ECM and carriers with subepidermal ECM from white donors did not affect NC cell migration in white or dark embryos. In contrast, subepidermal ECM from dark donors triggered NC cell migration in the subepidermal space of both white and dark hosts. Remarkably, subepidermal ECM from white donors which were older than those normally used also stimulated migration in embryos of both strains. Likewise, medial ECM from white donors elicited migration in white as well as dark hosts. Pigment cells occurred among those NC cells that were stimulated to migrate in response to contact with ECM on carriers. These results indicate that the subepidermal ECM of the white embryo is transiently defective as a substrate for pigment cell migration, implying that "maturation" of the ECM is retarded beyond the times during which pigment cells are able to respond. In contrast, the medial ECM of the white embryo appears to mature normally. These findings suggest that the effect of the d gene is expressed regionally through the subepidermal ECM during a limited period of development. Hence, the action of the d gene seems to retard ECM maturation, bringing it out of phase with the migratory capability of the pigment cells. We propose that such a shift in relative timing of the developmental phenomena involved inhibits pigment cell migration in embryos of the white axolotl mutant and, accordingly, that the restricted pigmentation of the mutant larva is generated through heterochrony.     

Neural crest cell behavior in white and dark larvae of Ambystoma mexicanum: time-lapse cinemicrographic analysis of pigment cell movement in vivo and in culture

The pattern of migration and motile activity of developing pigment cells of the Mexican axolotl, Ambystoma mexicanum, were analyzed by time-lapse cinemicrography in vivo and in culture. In vivo, melanocytes of dark (D/-) larvae migrate from dorsal to ventral in a highly directional manner. They are elongated and aligned parallel to the direction of migration. Nearly all protrusive activity occurs at their ventral, leading edges. Translocation occurs at a mean rate of 0.7 micron/min and involves alternate or simultaneous advance of the leading and trailing edges of the cell. Indirect evidence suggests that cytoplasmic flow is common. Directional migration occurs in apparent absence of contact between melanocytes. In white (d/d) larvae, protrusive activity is infrequent and the melanocytes move slowly or not at all. Explanted neural crest cells of dark and white larvae attach, spread, and differentiate into melanophores and xanthophores in culture. Individual cultured cells are unbiased in direction of protrusive activity and path of migration. Centrifugal spreading occurs by contacting inhibition of movement. Distribution of protrusive activity, polarity, and contact behavior changes with developmental age in vivo and in culture in ways that may be important in establishing the pigment pattern.     

Specific features of the melanophore system in different color morphs of larvae of the common toad (Bufo bufo L.)

In a natural pond among usual black larvae of the common toad (Bufo bufo L.), a few unusual individuals of red-olive coloring were found out. In both morphs we investigated the melanophores of skin using different methods. The ESR-spectrometric analysis has shown the absence of distinctions between morphs by the amount of melanin. Analysis of total preparations of skin has shown the presence of various kinds of melanophore cells both in the derma and in the epidermis. Among typical melanophores, essentially differing cells appeared (atypical cells). In black morph tadpoles, the number of all kinds of melanophores is significantly greater than in red-olive morphs. It is shown that dark coloring is connected with a considerable number of atypical cells in the epidermis imposed on a dense layer of typical dermal melanophores with dispersed melanin.     

Structural and compositional divergencies in the extracellular matrix encountered by neural crest cells in the white mutant axolotl embryo

The skin of the white mutant axolotl larva is pigmented differently from that of the normal dark due to a local inability of the extracellular matrix (ECM) to support subepidermal migration of neural crest-derived pigment cell precursors. In the present study, we have compared the ECM of neural crest migratory pathways of normal dark and white mutant embryos ultrastructurally, immunohistochemically and biochemically to disclose differences in their structure/composition that could be responsible for the restriction of subepidermal neural crest cell migration in the white mutant axolotl. When examined by electron microscopy, in conjunction with computerized image analysis, the structural assembly of interstitial and basement membrane ECMs of the two embryos was found to be largely comparable. At stages of initial neural crest cell migration, however, fixation of the subepidermal ECM in situ with either Karnovsky-ruthenium red or with periodate-lysine-paraformaldehyde followed by ruthenium red-containing fixatives, revealed that fibrils of the dark matrix were significantly more abundant in associated electron-dense granules. This ultrastructural discrepancy of the white axolotl ECM was specific for the subepidermal region and suggested an abnormal proteoglycan distribution. Dark and white matrices of the medioventral migratory route of neural crest cells had a comparable appearance but differed from the corresponding subepidermal ECMs. Immunohistochemistry revealed only minor differences in the distribution of fibronectin, laminin, collagen types I, and IV, whereas collagen type III appeared differentially distributed in the two embryos. Chondroitin- and chondroitin-6-sulfate-rich proteoglycans were more prevalent in the white mutant embryo than in the dark, especially in the subepidermal space. Membrane microcarriers were utilized to explant site-specifically native ECM for biochemical analysis. Two-dimensional gel electrophoresis of these regional matrices revealed a number of differences in their protein content, principally in constituents of apparent molecular masses of 30-90,000. Taken together our observations suggest that local divergences in the concentration/assembly of low and high molecular mass proteins and proteoglycans of the ECM encountered by the moving neural crest cells account for their disparate migratory behavior in the white mutant axolotl.     

Dosage effects of the white (d) and melanoid (m) genes on pigment pattern in the Mexican axolotl,Ambystoma mexicanum,Shaw

Two unlinked autosomal recessive genes, white (d) and melanoid (m), are known to affect wild-type coloration in the axolotl. The d allele in the homozygous recessive condition reduces the total number of melanophores and restricts their migration to the top of the head and along the spinal column. The m allele in the homozygous recessive condition increases the number of melanophores and effects a more uniform distribution. The action of these genes was further investigated by studying the phenotypes of triploid larvae of known genotype at the d and m loci. Triploidy was induced by heat treating the eggs immediately after oviposition to inhibit the second maturation division. Triploidy was verified by chromosomal counts in epidermal cells of tail-tip preparations. Melanophore distribution and number were recorded at 16 and 30 days after oviposition. Two d alleles in Ddd triploids effect a reduction in melanophore number and their rate of proliferation, but have no effect on melanophore distribution. Two m alleles in Mmm triploids effect an increase in the number of melanophores and their rate of proliferation, but have no effect on their distribution. Therefore, it appears that there are at least two separate physiological actions of gene D and M, one that determines melanophore distribution and another that determines their number and rate of proliferation.     

Description and ecology of larvae and juveniles of three native cypriniforms of coastal southern California

Larval series of the Santa Ana sucker, Catostomus santaanae (Federally Threatened), arroyo chub, Gila orcutti (California Species of Special Concern), and Santa Ana speckled dace, Rhinichthys osculus (California Species of Special Concern) are described from wild-caught specimens from the Los Angeles and Santa Ana river drainages. Santa Ana sucker larvae are elongate, having 41–46 myomeres and a distinctive paired-triangle patch of melanophores over the midbrain. Melanophores present on the snout, dorsal body, lateral midline, dorsal gut, postanal ventral body, and caudal fin. Preanal length 74–79% in body length (BL), typical of catostomids. Arroyo chub larvae relatively deep-bodied, 36–39 myomeres, and a heart-shaped patch of melanophores over the midbrain with a line of melanophores trailing posteriorly. Heavy pigment present on the snout, lower jaw, dorsal body, lateral midline, gill arches, dorsal gut, postanal ventral body, and caudal fin; short preanal length of 65–72% BL, typical of native North American cyprinids. Santa Ana speckled dace are similar to arroyo chub except for having less pigment on the ventral gut, large distinct melanophores on the ventrolateral caudal peduncle, a wedge-shaped patch of midbrain melanophores with no distinct line trailing posteriorly, and lateral midline melanophores that do not extend anteriorly. These three species often occur together and with nonnative cyprinids. Characters distinguishing them from other local larvae, including southern fathead minnow, Pimephales promelas confertus and red shiner, Cyprinella lutrensis, are discussed with their habitat preferences.     

Formation of pigment cell patterns in Triturus alpestris embryos

The distribution of melanophores and xanthopores in developing tailbud stages of Triturus alpestris was investigated. In stage 27 embryos (curved tailbuds), melanophores are distributed evenly but sparsely over the entire dorsolateral trunk. With progressive development melanophores arrange themselves into compact dorsal and lateral bands present in stage 34 embryos (9 to 10-mm-long larvae). On the inner surface of detached pieces of skin from early tailbuds which were investigated in the scanning electron microscope xanthophores were discovered in addition to and mixed with melanophores. Unlike melanophores they are invisible from outside. Later in development they occupy the zone between the melanophore bands and also the dorsal fin. Thus, formation of pigment cell patterns in Triturus embryos is a process which seems to depend on the differential sorting out of two populations of neural crest-derived chromatophore cell types.     

The influence of long-term chromatic adaptation on pigment cells and striped pigment patterns in the skin of the zebrafish, Danio rerio

The striped pigment patterns in the flanks of zebrafish result from chromatophores deep within the dermis or hypodermis, while superficial melanophores associated with dermal scales add a dark tint to the dorsal coloration. The responses of these chromatophores were compared during the long-term adaptation of zebrafish to a white or a black background. In superficial skin, melanophores, xanthophores, and two types of iridophores are distributed in a gradient along the dorso-ventral axis independent of the hypodermal pigment patterns. Within one week the superficial melanophores and iridophores changed their density and/or areas of distribution, which adopted the dorsal skin color and the hue of the flank to the background, but did not affect the striped pattern. The increases or decreases in superficial melanophores are thought to be caused by apoptosis or by differentiation, respectively. When the adaptation period was prolonged for more than several months, the striped color pattern was also affected by changes in the width of the black stripes. Some black stripes disappeared and interstripe areas were emphasized with a yellow color within one year on a white background. Such long-term alteration in the pigment pattern was caused by a decrease in the distribution of melanophores and a concomitant increase in xanthophores in the hypodermis. These results indicate that morphological responses of superficial chromatophores contribute to the effective and rapid background adaptation of dorsal skin and while prolonged adaptation also affects hypodermal chromatophores in the flank to alter the striped pigment patterns.     

Different distribution of melanophores and xanthophores in early tailbud and larval stages inTriturus alpestris

Summary The subepidermal distribution of xanthophores and melanophores is investigated in embryos ofTriturus alpestris with a uniform (stage 28+) and a banded melanophore pattern (stage 35/36). In ultrathin head and trunk sections from stage 35/36 embryos which externally show longitudinal dorsal and lateral melanophore bands in the trunk and less compact continuations of the dorsal bands in the head, xanthophores were discovered in addition to melanophores. Melanophores contain melanosomes while xanthophores which are not externally visible, are recognized by their pterinosomes. Both chromatophore cell types are mutually exclusively distributed on the epidermal basement membrane (bm). Mesenchymal cells seemed not to be able to replace them, except on the bm of the corneal epithelium where there were only mesenchymal cells. In head and trunk sections from stage 28+ embryos which externally show a distribution of uniformly scattered melanophores on the dorsolateral halves, melanophores were found on the dorsolateral neural crest migration route. No epidermal bm was present and xanthophores were undetectable. In ventrolateral and ventral portions of embryos of both stages no chromatophores occurred. This investigation defines the histological localization of melanophores and xanthophores in embryos with a typical uniform and banded melanophore arrangement; a subsequent study analyzes when xanthophores appear and how they arrange with melanophores in alternating zones.     

Adult-type pigment cells,which color the ocular sides of flounders at metamorphosis,localize as precursor cells at the proximal parts of the dorsal and anal fins in early larvae

Flounders form left-right asymmetry in body coloration during metamorphosis through differentiation of adult-type melanophores and xanthophores on the ocular side. As the first step in investigating the formation of flounder body coloration asymmetry, in this study, we aimed to determine where the precursors of adult-type chromatophores distribute in larvae before metamorphosis. In Paralichthys olivaceus and Verasper variegatus, GTP cyclohydrolase 2 (gch2), a common marker of melanoblasts and xanthoblasts, was found to be transiently expressed in cells located along the bilateral skeletal muscles at the basal parts of the dorsal and anal fins of premetamorphic larvae. When V. variegatus larvae were fed with a strain of Artemia collected in Brazil, this gch2 expression was abolished and the differentiation of adult-type melanophores was completely inhibited, while the density of larval melanophores was not affected. In a cell trace test in which the cells at the basal part of the dorsal fin were labeled with DiI at the premetamorphic stage, adult-type melanophores labeled with DiI were found in the skin on the ocular side after metamorphosis. These data suggest that, in flounder larvae, adult-type melanophores are distributed at the basal parts of the dorsal and anal fins as unpigmented precursor cells.     

Formation of the Dermal Chromatophore Unit (DCU) in the Tree Frog Hyla Arborea

In the tadpole of the tree frog Hyla arborea, the color of the dorsal skin was dark brown. Dermal melanophores, xanthophores, and iridophores were scattered randomly under the subepidermal collagen layer (SCL). After metamorphosis, the dorsal color of the animal changed to green and the animal acquired the ability of dramatic color change, demonstrating that the dermal chromatophore unit (DCU) was formed at metamorphosis. Fibroblasts invaded the SCL and divided it into two parts: the stratum spongiosum (SS) and the stratum compactum (SC). The activity of collagenase increased at metamorphosis. The fibroblasts appeared to dissolve the collagen matrix as they invaded the SCL. Then, three types of chromatophores migrated through the SCL and the DCU was formed in the SS. The mechanism how the three types of chromatophores were organized into a DCU is uncertain, but different migration rates of the three chromatophore types may be a factor that determines the position of the chromatophores in the DCU. Almost an equal number of each chromatophore type is necessary to form the DCUs. However, the number of dermal melanophores in the tadpoles was less than the number of xanthophores and iridophores. It was suggested that epidermal melanophores migrated to the dermis at metamorphosis and developed into dermal melanophores. This change may account for smaller number of dermal melanophores available to form the DCU_s.     

Effects of fetal bovine serum and serum-free conditions on white and dark axolotl neural crest explants

Summary Neural crest cells from both white mutant and dark (wildtype) axolotls (Ambystoma mexicanum) were cultured in increasing concentrations of fetal bovine serum (FBS; 2 to 20%). For each explant, the total number of cells that migrated and the percent of differentiated melanophores were recorded. At concentrations of FBS above 2% melanophore differentiation was essentially equivalent (32 to 59%) for both the white and dark neural crest cultures, but subtle differences in cell behavior and differentiation were found between the two phenotypes. By contrast there was a significant difference in the percent melanization of cells in serum-free control cultures, wherein melanophore differentiation in dark neural crest cultures was, on average, 18% compared to 5% in white cultures. Thus, contrary to all previously published work, white and dark neural crest cells are not intrinsically equivalent. Our culture results are discussed with regard to the probable in vivo conditions that cause the white phenotype. This research was supported by grant AR 34478 from the National Institutes of Health, Bethesda, MD, and a University of Kansas Biomedical Science support grant.     

Immunohistochemical demonstration of hyaluronan and its possible involvement in axolotl neural crest cell migration

Hyaluronan (HA), an extracellular matrix component, is involved mainly in the control of cell proliferation, neural crest and tumor cell migration, and wound repair. We investigated the effect of hyaluronan on neural crest (NC) cell migration and its ultrastructural localization in dark (wild-type) and white mutant embryos of the Mexican axolotl (Ambystoma mexicanum, Amphibia). The axolotl system is an accepted model for studying mechanisms of NC cell migration. Using a biotinylated hyaluronan binding protein (HABP), major extracellular matrix (ECM) spaces, including those of NC cell migration, reacted equally positive on cryosections through dark and white embryos. Since neural crest-derived pigment cells migrate only in subepidermal spaces of dark embryos, HA does not seem to influence crest cell migration in vivo. However, when tested on different alternating substrates in vitro, migrating NC cells in dark and white embryos prefer HA to fibronectin. In vivo, such an HA migration stimulating effect might exist as well, but be counteracted to differing degrees in dark and white embryos. The ultrastructural localization of HA was studied by means of transmission electron microscopic immunohistochemistry using HABP and different protocols of standard chemical fixation, cryofixation, embedding, and immunolabeling. The binding reaction of HA to HABP was strong and showed an equal distribution throughout ECM spaces after both standard chemical fixation/freeze substitution and cryofixation. A preference for the somite or subepidermal side was not observed. Following standard fixation/freeze substitution HABP-labeled "honeycomb"-like networks reminiscent of fixation artifacts were more prominent than labeled fibrillar or irregular net-like structures. The latter predominated in adequately frozen specimens following high-pressure freezing/freeze substitution. For this reason fibrillar or irregular net-like structures very likely represent hyaluronan in the complex subepidermal matrix of the axolotl embryo in its native arrangement.     

Chromatophoromas in a pine snake

Iridophoroma and melanophoroma were diagnosed in an adult male pine snake. Light microscopic examination of irregularly thickened white and black portions of abnormal scales demonstrated two distinctive populations of pigment-containing cells. Pigment cells within abnormal-appearing white scales had needle-shaped granules that were dark amber in color while black portions were composed of pigment cells typical of melanophores, with dark black, round granules. Both populations of cells showed junctional activity, and clusters of both neoplastic pigment cell types were found in adjoining areas of the epidermis. By electron microscopy, the pigment cell with amber-colored granules contained reflecting platelet profiles typical of iridophores while pigment cells with dark round granules contained melanosomes. At a junctional area between abnormal white and black scales, mosaic chromatophores containing reflecting platelet profiles and melanosomes were observed. At 1 1/2 years following initial diagnosis, the snake died and neoplastic iridophores were found at multiple visceral sites; there was no evidence of metastases of melanophores to any organ. The two pigment cell tumors are believed to have developed from either stem cells destined to become iridophores and melanophores or from prexisting iridophores and melanophores in the dermis.     

Observations on the development of unusual melanization of leopard frog ventral skin

The ontogeny of ventral pigmentation of two species of leopard frog, Rana pipiens and R. chiricahuensis, was examined by light microscopy and transmission electron microscopy to reveal how the unusual melanistic ventral pigmentation of R. chiricahuensis is achieved at the cellular level. Ventral skin of R. pipiens is always white. Ventral skin of adult R. chiricahuensis is white when frogs are background-adapted to a white substrate, but ventral skin becomes nearly as dark colored as the dorsal skin when frogs darken in response to a black background. Skin samples from tadpoles of both species, newly metamorphosed frogs, and adult frogs were analyzed for chromatophore composition and distribution. Ventral skin of R. pipiens larvae, newly metamorphosed frogs, and adults and of R. chiricahuensis larvae was white due to abundant iridophores and no melanophores. Melanophore density in the ventral integument of R. chiricahuensis was 9.1 ± 2.8/mm² in newly metamorphosed frogs and 87.0 ± 4.8/mm² in adult frogs. Pigment within ventral melanophores migrated during physiological color change during background adaptation. © 1993 Wiley-Liss, Inc.     

Secondary coverage of the yolk by the body wall in the direct developing frog, Eleutherodactylus coqui: an unusual process for amphibian embryos

 Eleutherodactylus coqui develops directly from a large 3.5-mm egg to a froglet, without an intervening tadpole stage. We have examined the development of the body wall, a structure whose behavior has been altered in this derived development. In an event that is unusual for amphibian embryos, the yolk mass is secondarily surrounded by the body wall, which originates near the embryo’s trunk. The epidermis of the body wall is marked by melanophores, and the rectus abdominis, which will form the ventral musculature, is near its leading edge. As the body wall expands, the epidermis, melanophores, and rectus abdominis all move from the dorsal side to close over the yolk at the ventral midline. The original ectoderm over the yolk undergoes apoptosis, as it is replaced by body wall epidermis. Intact muscles are not required for ventral closure of the body wall, despite their normal presence near the advancing edge. Comparative examination of embryos of Xenopus laevis and Rana pipiens suggests that ventral closure does not occur in species with tadpoles. The expansion of dorsal tissues over the yolk, as illustrated by E. coqui, may have been important in the origin of amniote embryos. Received: 23 April 1998 / Accepted: 28 June 1998     

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.     

Cuticular encystment of Autographa nigrisigna eggs by epidermal cell migration

It was previously established that Autographa nigrisigna loopers form cuticular cysts at the dorsal site of the 9th (penultimate) abdominal segment after parasitization by the solitary endoparasitoid Campoletis chlorideae and get rid of the parasitoid egg with the old cuticle at ecdysis. The cuticular cyst consists of a space between the old cuticle and new cuticle formed by the epidermis to enclose the parasitoid egg. The fact that A. nigrisigna loopers exclude the oviposited egg from the hemocoel using a cuticular cyst raises the question how the parasitoid egg passes through the epidermis. To exclude the endoparasitoid eggs from the hemocoel, the epidermis is required to move the location of the parasitoid egg. In the current study, we investigated the morphological process of cuticular cyst formation. First, the oviposited egg drifted to the 9th abdominal segment located at the open end of the dorsal vessel as a result of force generated by the hemolymph current from the oviposition site, and formed contacts with the integument containing the fat body (FB). The epidermis, in contact with the egg, then began to move along with the basement membrane formed on the surface of the FB, and settled under the egg, thus altering its location. This inversion was duplicated in vitro using integument from the 9th abdominal segment when parasitoid eggs were inserted between the epidermis and FB. When the integument, without the FB, was incubated on an agar plate, the epidermal cells migrated on the plate. Integument without eggs showed no signs of migration from their original sites. When the actin polymerization inhibitor latrunculin B was added to the cultures, the epidermal cells remained in their original location.     

Stimulation of initial neural crest cell migration in the axolotl embryo by tissue grafts and extracellular matrix transplanted on microcarriers

The present experiments were designed to test whether the onset of neural crest cell migration in the embryonic axolotl trunk is stimulated by surrounding tissues and their associated extracellular matrix (ECM). Tissue grafts, or embryonic ECM adsorbed in vivo onto inert "microcarriers" prepared from Nuclepore filters, were placed close to the premigratory neural crest cells, and the embryos were then incubated to a specific stage. The experiments were evaluated with light microscopy, SEM, and TEM. It was found that grafts from the dorsal epidermis were especially effective in locally stimulating initial neural crest cell migration in the region under the graft. The microcarrier experiments showed that the subepidermal ECM alone could initiate neural crest cell migration, implying that the ECM of the epidermal grafts was the stimulating factor. These results indicate that the premigratory neural crest cells along the trunk have migratory capability but that they need to be triggered from the environment, probably from the surrounding ECM, to start migration. It is proposed that ECM, as substrate for cell locomotion, initiates and regulates the onset of neural crest cell migration.